DE1161707B - Device for registering the core lengths of flames with initial air admixture and setting of gas parameters - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Boarding school Kl .: GOIn

German KL: 421-4 / 07

Number: 1 161 707

File number: V 22236IX b / 421

Filing date: March 19, 1962

Opened on: January 23, 1964

The invention relates to a device for direct measurement and ongoing registration of the so-called Core length, the height of the cone of a gas flame that forms the primary combustion zone, to which part of the air required for combustion is distributed through premixing with the gas. At the same time, this device can be used to set detonated gas indicators.

Cone height determinations are for example according to the known determination of the ignition speed the dynamic method of Gay-Michelson is required. Methods are known to reduce the The core lengths of flames can be observed optically and the respective focal cone height can be measured using a cathetometer to eat. A device for the ongoing registration of the focal cone height, for example for the purpose the control of the gas generation with regard to setting a certain quality of the gas with regard to its Ignition rate is not yet known. The requirement, the burning properties of fuel gas mixtures to be identified by continuously measurable key figures and according to them Being able to intervene in a corrective or regulating manner therefore makes a deficiency particularly noticeable.

It is also a so-called Schnellgasprüfer hi connection with a hydraulic or pneumatic one Known regulator, in which a small cauldron, which is filled with ether, the flanks of the cone and the steam pressure, which increases due to heating as the cone becomes shorter, once that Gas-air ratio changes via a control so that the cone becomes longer again and on the other hand, if necessary controls the supply of a second gas via a regulator so that the ignition speed is kept constant.

The cross-section for the air distribution set on the test burner by the control, which is approximately proportional to the amount of air, then it is the measurand for what is called the "test burner number" Indicator according to which the uniformity of the gas quality can be assessed. However, this method is very indirect and does not reveal the magnitude of the effects of deviations correctly.

In contrast, the dimension of the burning cone height can be used directly for assessing the risk of lifting if the cone heights are too great or kickback if the cone heights are too small, for example on burner burners. When setting a certain first air number λ 1 as the ratio of the allocated first air amount to the stoichiometric amount of air necessary for complete combustion, for example a device for registering the core lengths
of flames with initial air admixture
and setting of gas codes

Applicant:

VEB Junkalor Dessau,

Dessau, Altener Str. 43

Named as inventor:
Dipl.-Ing. Peter Scheffler, Dessau

Xl = 0.5, the combustion cone height resulting from the uniformly agreed muzzle diameter and outflow velocity would directly form an advantageous characteristic number for the gas, which, together with the Wo'bbe number as a characteristic variable for the heat output, would enable a clear characterization for the purpose of exchangeability.

The invention is based on the object of providing a device for direct measurement and ongoing registration of the height of the primary combustion zone forming a cone of a gas flame that pre-mixes part of the air required for combustion with which gas is allocated to create.

This device should at the same time enable the setting of an agreed initial air ratio Xl directly after the Wobbezabi, whereby the constancy of the setting or a necessary correction can be made by briefly activating a control measuring section.

This is achieved according to the invention in that the pressure increase by heating a, the Tip of a cone of the first combustion zone touching outlet nozzle of a narrow, in the flame axis a periscope-like extendable burner tube and a weak air flow through the probe line for the relative axial displacement of the probe line opposite the burner tube end is used against a Rüokführkraft metrological and advantageously on Burner tube a container filled with sealing liquid, in which a ring diving bell is guided, whose The interior space is connected to an extended probe line via a standpipe, is fixedly arranged.

In one embodiment and the schematically illustrated FIG. 1, the subject matter of the invention explained in more detail:

309 780/202

The burner tube 13 of a gas burner is designed to be extendable in the manner of a periscope. Its upper that as Orifice formed burner tube end 17 containing part 16 partially forms the inner jacket of a Ring diving bell 15, which is in the tightly enclosing, on the lower, fixed part of the burner tube 13 Soldered container 14 is seated, which contains the barrier liquid.

In the burner tube axis, a thin air line is guided upward as a probe line 18, whose as narrow outlet nozzle 20 formed and made of heat-resistant material mouth the primary combustion zone 19 touched at the top and this follows. That is to be considered relatively, because actually The ring dipping bell rises and falls, and with it the burner tube end 17 above the outlet nozzle 20 designed probe mouth. The probe mouth forms the »output throttle« of a pneumatic cascade circuit. From a pressure regulator 4, for example a blow-off pressure regulator, the air or the constant pressure gas via line 21 and choke 22 into the expanded probe line 23 sent, which is connected to the space under the diving bell at the same time via a standing pipe 24. the corresponding throttles and the form are matched so that the between them and below the Diving bell effective pressure the diving bell is not yet able to raise as long as it acts as an outlet nozzle 20 designed probe mouth as an output throttle is not heated. When heated, when touched the probe mouth with the primary combustion zone 19 takes place very intensively, the throttling effect stronger, the pressure rises, and the diving bell is raised until the primary combustion zone hits the muzzle no longer envelops and the temperature drops again or the state of equilibrium is established.

The relatively small probe air flow slightly falsifies the height of the focal cone, but this error can be calibrated. It is now possible to change the height of the diving bell directly below Display and register the interposition of a writing lever 26. The lifting movement can, however can also be transmitted by means of rope or chain 25 to one end of a lever 27, the other end of the lever The end shows a pendulum 28 with a top surface 29 that is always horizontally positioned. This top surface throttles the air outlet from a nozzle 30, which is the end of the bellows 36 arranged on a capsule Forms tube 35, the capsule bellows the air also from the line 21 via a throttle 31 is forwarded. When the diving bell 15 sinks, the top surface 29 approaches the nozzle 30 and throttles more, as a result of which the pressure in the capsule bellows 36 rises for so long and this increases accordingly expands until its expansion corresponds to the stroke of the top surface 29 and thus also that of the ring diving bell 15 corresponds and the nozzle begins to move away from the top surface again. Since the pressure in the capsule bellows can be set up proportionally to its expansion and via a branch 32 and trunk line 33 can be transferred to a printer 34, is thus also a remote registration on a or more than one printer possible.

The pressure can also be used to operate regulating devices. The type of setting of the gas-air mixture, which is very important for determining a gas index for flame stability (lifting and flashing back of Bunsen flames), can also advantageously be seen from the figure. The setting can then initially be made with air not only for the allocated initial air quantity 2, but also for the gas quantity 1, so that air can consequently also be sent through the gas line. First there is a pre-pressure regulation by means of the pressure regulator 3 for gas and pressure regulator 4 for air, wherein the pressure regulator 4 can be designed as a simple blow-off pressure regulator. The setting is then made

ίο at the adjusting throttles 5.

The amount flowing through is at those belonging to the pre-calibrated aperture measuring sections 7 and 8 Inclined tube manometers 9 can be read. The aperture of the aperture measuring section 7 must according to the DIN rules be profiled so that their flow is inversely proportional to the Root of density is.

The diaphragm measuring sections 7 and 8 are only switched on during the setting or control.

During the actual continuous operation they are bypassed by switching the three-way cocks 6, so that there is a direct feed line to the metering nozzles 11 and 12 of the mixer 10, in which prior to initiation homogeneous premixing takes place in the burner tube 13.

In front of the metering nozzles 11 and 12 there is a pressure that can also be measured with inclined tube manometers 9, which is related to the corresponding quantity and must be kept the same when the three-way cocks 6 are switched over. The rule for the setting for determining the gas number is as follows: If gas with the density ratio 1, i.e. air, is sent through the gas line, the ratio of the amount allocated and measured by the orifice measuring section 8 to the amount flowing through the gas line and through the Orifice measuring section 7 measured amount as the product of the Wobbe number, defined as the same heat of combustion by the square root of the density ratio, and the air number λ 1 divided by the ratio n, defined by the quotient of heat of combustion by the stoichiometric air requirement.

In addition, the sum of the two quantities should remain constant and be dimensioned so that the out-flow velocity from the nozzle is within a correct range for reproducibility. For this purpose, 80 to 200 cm per second can be selected for a mouth diameter of 10 mm, for example will.

The resulting focal cone heights are then in a certain ratio to the core lengths from permanently set Bunsen burners, such as stove burners in the household, and leave immediately the effects of changes in the quality of the gas on these core lengths and thus on the lift-off and Recognize backlash.

The measurements with this new device have, in addition to the registrability that is now possible, the other significant advantage that they take into account the practical conditions better than the previous ones Ignition rate measurements based on volume ratios because they are the direct adaptation of the Enable air distribution to the Wobbe number and take into account the changes in density of the escaping gas.

If the setting is made in such a way that air is also sent through the gas nozzle during setting is obtained, when operating with gas, the measured

I 161

This burning cone height as a directly usable gas index for assessing the effect of the gas quality on the stability behavior of burner flames.

Claims (6)

Patent claims: 1. Facility for direct measurement and ongoing registration of the height of the primary combustion zone forming a cone of a gas flame, which is part of the air required for combustion is allocated by premixing with the gas, characterized in that the pressure increase by heating a tip of the cone of the primary cremation zone (19) in contact Outlet nozzle (20) of a narrow, in the flame axis of a periscope-like extendable Burner tube (13) arranged and flowed through by a weak air stream probe line (18) for the relative axial displacement of the probe line with respect to the burner tube end (17) is used against a feedback force metrologically, further in that in one a tank (14) fixed to the burner tube and filled with sealing liquid (15) is guided, the interior of which is via a vertical tube (24) with an extended probe line (23) is connected. 2. Device according to claim 1, characterized in that the end of the probe line (18) as the outlet nozzle (20) and the beginning as the inlet nozzle of a pneumatic cascade circuit with constant pressure in front of the inlet nozzle and the pressure between the inlet and outlet nozzle is passed under a ring diving bell, the inner jacket of which is periscope-like Extension of the burner tube and its weight, the return force against the pressure increase by heating the outlet nozzle. 3. Device according to claim 1 and 2, characterized in that the change in height of the focal cone The lifting movement of the ring diving bell following the first combustion zone is transmitted to one end of the lever, the other end of the lever At the end, by means of the cover surface, the outlet opening of the tubular extension (35) of an air flow Capsule bellows (36) throttles in such a way that as a result of the associated increase in pressure the Kapselbaligdehnunig follows the stroke of the lever end and that of the capsule bellows expansion proportionally adjusting internal pressure of the capsule bellows by means of known Pressure recorder represents a recordable measure for the height of the cone of the flame. 4. Device according to claim 1 and 2, characterized in that the cone height change The stroke movement of the ring diving bell following the first combustion zone is transferred to a writing lever of a recording mechanism will. 5. Device according to claim 1 to 4, in which air and gas by means of metering nozzles are fed to a mixer, characterized in that the dosage before the mixer by means of Dosing nozzles and indicated pressure takes place and that a diversion takes place before the last pressure measuring point over a diaphragm measuring section with a profiled diaphragm adapted to the Reynold counters can be switched on. 6. Setting of the device according to claim 1 to 5 for metrological detection of a gas code, characterized in that air is sent through the gas line and the amount is adjusted by means of the aperture measuring sections (7 and 8) so that the ratio of the two amounts as a product of the Wobbe number and air ratio λ 1 divided by the empirical value η defined as the quotient of the heat of combustion by the stoichiometric air requirement and the sum of both quantities results in a constant and, according to experience, favorable outflow velocity from the burner mouth. 1 sheet of drawings 309 780/202 1.64 © Bundesdruckerei Berlin