CS198599B1 - Low-pressure torch especially for giant space furnace and air heaters - Google Patents

Description

( ⁵⁴ ) Low-pressure epheater burner, especially for high-speed furnaces and wind heaters

The invention ea relates to a low-pressure epheater burner with a slot air supply to the mixing chamber, in particular for large-volume furnaces and wind heaters, and solves the problem of high performance.

For large-scale peoes such as eu e.g. deep furnace reap. to heat the wind heaters, ea use burners without the addition of secondary air, or predominantly, and burners with free gas outflows and require relatively high air and media pressures of 5 to 10 Pa. Separate burners are required when using multi-media media. In the heater wind for the high peoe, the mixing space is reap. burning the shaft practically along the vertical height, from the burner located in the lower part of the shaft to the vault and bending and with the current down through the oes lattice to the exit to the chimney | after the heating is stopped, the flow direction is reversed for heating. The main disadvantage is that the incinerator shaft located in the heater limits the heat exchanger, causing uneven expansion of the lining of the shaft and filler due to the differences in temperature and the like. Also, in the case of the epalation shaft outside the heater, there are substantial heat losses in the epalation chamber above the heater using high-pressure ceramic burners. These are complicated gas distributions to the back of self-priming burners for the purpose of urged epailating before entering the heater, requiring thermal insulation, etc. The use of vortex burners for epilating solid powdery fuels requires high air pressure, and requires an auxiliary burner for gas or oil to preheat the epilating chamber.

19 · 599

19B589 is independent of and outside the main burner, So requires a long time, e.g. when heating the boiler. E.g. In addition, according to U.S. Pat. No. 123,441, a burner dome system for heater which uses only to distribute the flue gas evenly into the heater ducts, moreover, exhibits some disadvantages of the burner burner, with substantial heat losses in the unproductive dome preload.

The above-mentioned drawbacks are eliminated and the problem is solved by a low-pressure epalar burner, especially for large-scale pens and wind-heater, using a side-by-side air inlet to the emerge chamber. an annular manifold on which a rectangular chamber dome is located flush with the outer edge of the circumferential slot located at the top of the annular manifold, the air outlet emitter emitter being parallel to the inner wall of the bottom of the dome and at least one inlet duct . In order to adjust the slot size, an annular plug is preferably located in the annular distribution. The combustion medium supply situated at the top of the moderate dome preferably has a copper-in-circular supply of the next combustion medium, e.g. powder or liquid, as well as aces of oxygen, each of which is Bamoetatically controllable and all eu rectified in the discharge axis. The outlet throat and the lower exposed chassis of the annular manifold are provided with isolaole. In the case of a burner for an air heater, the dome rectifier is a lining of the heater dome and the combustion medium supply is a simultaneous discharge of the hot wind pipe with a separate outlet.

The advantages of the invention are mainly that it allows for sufficient and rapid mixing of large media volumes with a high efficiency of combustion, thus eliminating the need for multiple burners and allowing high incineration burdens and demands and wiring and preators. It is universally applicable, especially in closed large-area fields, eliminating the need for preheating the combustion shaft when using e.g. • a pulverulent fuel having an arbitrarily and operatively monolithic ratio of the burned media with controlled calorific values and uniform pressures.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS OF THE INVENTION are shown in the accompanying drawings, wherein FIG. 1 and 2 show a simple burner and multiple feeds of combustion media or supplementary oxygen; and FIG. 3 shows a burner for a wind heater in a copulo.

The burner consists of a stream air manifold 10 with a lateral inlet conduit 44 which surrounds the exhaust gas outlet 30 in a substantially cylindrical shape. A circular continuous circumferential slot 12 is formed in the upper part of the overhang 10, the outer edge 13 of which is formed by the inner stem 22 of the lower portion of the diminished dome 21 of the shrink chamber 20. The dome 21 of the chamber 20 has a pre-formed time? The walls 22 are religiously disposed in the flow direction 71 and are continuously rounded in the air flow direction. at the mouth of the incoming medium. When the burner is used in the dome of the heater 52, the wind dome 21 is formed by the lining of the dome 61 e preferably of a hemispherical shape.

188 B88

Flue outlet 30 and bottom time? The annular manifold 10 is lined with ceramic insulation 50. The dropped medium supply 40 consists of an axial inlet 41 of the base medium, respectively, an annular inlet 42 of another dropped medium and an optional pulverized or liquid fuel dispenser 43 or an additional axial oxygen supply 44 to increase the dropping effect or extend. breed.

In the burner, the air and the fallen medium are mixed in the dome-shaped mixed chamber 20, and at the same time rapid fall occurs already during the outflow from the flue gas outlet 30.

In the case of using a burner in the heater 60 wind, maybe creating? lattice 62 to the outlet throat χθ of the flue gas respectively. to one of the mounting spaces 63, as well as the disconnected fall-off medium supply 40 with a separate outlet, can one? used to remove the heated wind.

Burners subject to the invention can indulge? except wind heaters eg. for the digging of deepwater boilers, boilers, and wherever high output is required for low pressurized media, low calorific values, frequent shutdowns and start-ups. with the need for frequent changes in media usage, etc.

Claims (5)

3 188 B88 Flue gas outlet 30 and bottom time? The inlet 40 of the fallen medium consists of an axial inlet 41 of the base medium, or an increase in the effect of epading or breed extensions from the annular inlet 42 of the other fallen medium and the optional spray or liquid fuel dispenser 43 or additional oxygen inlet 44. In the burner, the mixed air with the fallen medium in the dome-shaped mixing chamber 20a simultaneously falls rapidly during the discharge through the flue outlet 30 of the flue gas. In the case of using a burner in a heater 60, can it be generated? the grid 62 up to the outlet orifice 40 of the flue gas or the flue gas outlet itself; to the mounting spaces 63, wherein one of the mounting spaces 63 is the same as the disconnected inlet 40 of the spraying medium with a separate outlet, which may be used to remove the heated wind. Can burners burn according to the invention? in addition to heaters, for example, for heating and damp pellets, spill boilers, and wherever high heating power is required at low media pressures, with low calorific value, with the need for frequent shutdowns and retardation. with the need to change the usage rates of individual media frequently from below. DISCLOSURE OF THE INVENTION 1. A low-pressure fall burner, in particular for space-fired furnaces and air heaters with a side air inlet and a slot outlet into a mixing chamber, characterized in that the air conduit is located close to the periphery of the exhaust gas outlet (30) formed in the form of an annular conduit (10) on which the dome (21) of the mixing chamber (20) is positioned flush with the outer edge (13) of the circumferential slot (12), in the upper part of the annular distribution (10), wherein the air outlet direction (71) is normal with an inner wall (22) of the lower portion of the baffle dome (21) on which at least one fallen medium inlet (40) is disposed. 2. A low-pressure drop burner according to claim 1, wherein a plug-in throttle ring (14) is provided in the annular divider (10) along the periphery of the outlet neck (30). 3. A low-pressure drop burner according to claim 1, wherein the inlet (40) of the dropped-in conduit consists of an axial conduit (41) and a coil of at least one annular conduit (42) of another falling medium with an atomiser (43), e.g. , located in the outlet mouth as well as from the additional oxygen inlet (44), all of which are directed into the exhaust gas discharge direction (72) and each is separately controllable. 4. The low-pressure fall burner according to claim 1, wherein the outlet orifice (30) and the exposed time? the annular distribution (10) is insulated (50). 5. A low pressure drop burner as claimed in claim 1, wherein the orifice dome (21) is formed by a dome lining (61) of the heater (60) and the inlet (40) of the fallen medium is simultaneously formed as an outlet for the hot air duct with a separate outlet. 3 drawings