RU2348863C2 - Flameless infra-red heater - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: invention relates to heating devices with temperature radiators being heated by fuel and air mixture burning in flameless mode for heating mainly road covering during maintenance operations. The flameless infra-red heater of road covering includes enclosed radiating perforated panel with through channels. The panel is mounted in the housing and made of refractory ceramics. From the outside, the panel is protected with refractory mesh. The heater also includes injector linked with gas balloon and air intake. Besides, together with the inner cavity, the radiating refractory panel forms a working chamber. There is a distributor of gas and air mixture. The radiating panel is installed in the lower part of the housing and directed to the road covering when it is in working position. The injector with air intake is represented with common injection and mixing unit being installed outside the housing and shifted with regard to its centre and connected with pipeline body. The pipeline is introduced into the housing in the centre of the upper surface and ends up with nozzle projected into the working chamber. The air and gas distributor is made in the form two metal plates of different length. The plates are fixed to the inner surface of the housing from the opposite sides with regard to the free edges of the plates being one above the other and overlapping the next one along the whole length. The plates overlap the working chamber by the cross section area. Besides, the short metal plate is installed close to the radiating perforated panel. The long metal plate is tilted to the side of radiating perforated panel. There are gaps between the long metal plate and nozzle from the one panel side and short metal plate from the other panel side. There is a hollow along the long metal plate axis. The hollow is in the form of spherical surface segment. Its radius is equal to the nozzle radius coupled with the segment of spherical surface. The nozzle is directed to the free edge of the long metal plate by its larger diameter. The air intake is represented with two coaxial hollow cylinders of different length. The short cylinder of smaller diameter is provided with an open-ended perforation. There are open-ended slots on the long cylinder along its moving line and to the length of the short cylinder perforation. Both cylinders are interconnected by flanges with the injector being installed on its axis. The tapered part of the injector with the channel opening on the cone point for gas discharge are available inside the short cylinder of the smaller diameter. The cylinder part is linked with the pipeline supplying gas from the reservoir. Besides, the cylinder with larger diameter is linked with the air-gas mixture supply pipeline on the free end. The short plate overlaps radiating perforated panel by no more than 0.2 of its area.

EFFECT: increase of heater operation effectiveness under any weather conditions.

3 cl, 3 dwg

Description

The invention relates to heating devices with temperature radiators heated by a combustible air-fuel mixture in flameless mode, mainly for heating a road surface in the process of repairing it.

Infrared heating devices are widely used in special road repair machines when removing asphalt pavement to soften it and prepare for removal (see, for example, US patent No. 4534674 according to class E01C 23/06, publication 1985, German patent No. 10145007 C. E01C 23/14, publication of 2003).

Infrared flameless heating devices operating on a gas-air mixture are known and use a panel with refractory ceramic channels as a radiating element (Russian patent No. 2065123 according to CL F23D 14/14, publication 1996) or a porous catalytic panel made of metal or ceramic (for example , Russian patent No. 21116568 according to class F23D 14/18, 1998 publication). Such heating devices are simple in design, economical and are mainly used for heating and drying domestic industrial premises and other industrial purposes. Structurally, these heating devices are designed so that their radiating elements are located in the upper part of the device, and the jet nozzle connected to the gas cylinder and a diffuser mounted with an injection hole for intake of atmospheric air in the working chamber, under the radiating panel. This design of the heating device does not allow its use in road works, when the radiating element itself should be in the lower part of the device in close proximity to the road surface.

The closest in technical essence and in the number of common features to the proposed device is a flameless infrared heater described in the book by A.I. Bogomolov, D.Ya. Vidgorchik, M.A. Maevsky. "Gas burners of infrared radiation and their application." M., 1967, p. 32-35.

The flameless infrared prototype heater contains a housing, in the upper part of which a radiating element is mounted in the form of a panel of refractory ceramics with through channels with a diameter of 1-1.5 mm. A nozzle connected to a gas source (gas cylinder) is mounted in the side wall of the housing. The injector-mixer is made in the form of a Venutri pipe, in the throat of which there is a nozzle and an air intake - an opening through which atmospheric air, forming a gas-air mixture with gas, enters the working chamber of the heater. Venturi pipe in this design also performs the function of a distributor of air-gas mixture. On the outside, to intensify the combustion of gas and equalize the temperature on the surface of the radiating panel, a metal mesh of refractory material is installed. Close to the stoichiometric composition of the gas-air mixture, good mixing of the gas with air and a low exit speed of the mixture allows it to be burned on the surface of the ceramic panel in a thin layer.

With an increased suction of primary air, which can be caused by wind or atmospheric pressure drops when working in the open air, the temperature on the radiating panel drops, and the radiating ability of the prototype heater decreases. With reduced suction, tongues of flame appear and incomplete combustion occurs, which worsens the operation mode of the heater.

The disadvantage of the prototype heater is that the efficiency of the prototype heater is significantly reduced from the angle of inclination of the radiating panel. The lowest efficiency becomes at an angle of rotation of the radiating panel by 180 ° (the book "Gas burners and their application", p.38), i.e. when the radiating panel is at the bottom, as is the case when the road surface is heated, a significant heating of the case occurs, which, in turn, leads to loss of thermal energy. The working chamber of the heater of the described construction is not protected from clogging through the opening of the air intake with waste products in which the heater is used.

The technical result from the use of the proposed invention is to increase the efficiency when heating the pavement, including ensuring stable operation in the open air and maintaining the parameters of heating and combustion, regardless of atmospheric conditions, ensuring that there is no loss of body from heating the housing, as well as protection against clogging of the working chamber with waste road production.

To ensure the specified technical result, a flameless infrared heater of the road surface, comprising a radiating perforated ceramic panel with through channels mounted in the housing, is closed on the outside with a mesh of refractory material, a nozzle connected to the gas cylinder, and an air intake, while the fireproof radiating panel forms a working chamber with an internal gas chamber in which the distributor of the gas-air mixture is located, new features are introduced, namely: the radiating panel is installed in the lower part of the casing and in the working position is facing the road surface, the nozzle with the air intake is made as a single injection-mixing unit installed outside the casing with an offset relative to its center and connected to the casing by a pipe introduced into the casing in the center of its upper surface and ending with a pipe protruding into the working chamber, and the distributor of the gas-air mixture is made in the form of two metal plates of different lengths, fastened along the contour with the morning surface of the housing from the relatively relatively free edges of the plates one above the other with approaching one after another in length and overlapping the working chamber by its cross-sectional area, the short metal plate being installed closer to the radiating perforated panel, the long metal plate is inclined towards the radiating perforated panel, there are gaps between the long metal plate and the pipe on one side of it and the short metal plate on its other side, and about and long metal plate a recess at the nozzle axis shaped as a spherical segment surface whose radius is equal to the radius of the pipe, the articulated with the segment of a conical surface the large diameter facing the free edge of a long metal plate.

To ensure optimal conditions for creating a stoichiometric composition of the gas-air mixture, the air intake of the injection-mixing unit is made in the form of two coaxial hollow cylinders of different lengths, a short cylinder of smaller diameter has through perforation, through a long cylinder of larger diameter there are through slots along its length along the perforation of the short cylinder, both cylinders at one end are connected by a flange, along the axis of which a nozzle is installed, the conical part of which is with an opening for the gas outlet the top of the cone is inside a short cylinder of smaller diameter, and the cylindrical part is connected to the pipeline supplying gas from the cylinder, while at the free end the cylinder of larger diameter is connected to the pipeline for supplying the gas-air mixture.

To fully and evenly provide the radiating perforated panel with a gas-air mixture during combustion, the short metal plate should not overlap the radiating perforated panel by more than 0.2 of its area.

The execution of the nozzle with a gas intake in the form of a single injection-mixing unit of the proposed design and its removal outside the working chamber and the housing of the claimed heater allow for constant pressure drops inside and outside the working chamber regardless of atmospheric environmental conditions when installing a radiating panel in the immediate vicinity of the road surface to ensure the constancy of the radiation temperature up to 1000 °, as well as during the operation of the prototype heater during its operation in normal mode, and protection from clogging the working chamber. At the same time, the proposed design of the gas distributor provides convection of the gas-air mixture in the working chamber, which avoids heating of the housing.

The invention is illustrated figure 1-3, while figure 1 shows the design of the proposed heater, figure 2 - the design of the injection-mixing unit, figure 3 - the design of a long plate.

The proposed flameless infrared heater of the road surface (Fig. 1) contains a radiating perforated panel 1 mounted in the lower part of the metal housing 2. The panel 1 is made of ten plates of refractory ceramics perforated through channels 3 with a diameter of 1.2 mm. The plates are glued together at the edges. The thickness of the radiating panel is approximately 12 mm; its dimensions are 250 × 150 mm. On the outer side facing the road surface, the radiating panel is closed by a grid 4 of refractory metal. The distance from the radiating panel to the grid is 10 mm. To the upper surface of the housing 2 in its center is a pipeline 5 of a gas-air mixture with a diameter of 30 mm, which ends with a pipe 6, protruding into the working chamber 7 by 14 mm. The height of the working chamber is 45 mm.

At the opposite end of the pipeline 5, having an L-shaped shape, an injection-mixing unit 8 is installed with an offset relative to the center. Unit 8 (FIG. 2) consists of a short 9 and a long 10 coaxial cylinders. Perforation is made on the cylinder 9 evenly over its surface — through holes 11 with a diameter of about 3 mm. On the cylinder 10 along its generatrix, through slots 12 are made for the length of the perforation of the cylinder 9. The cylinders 9 and 10 are connected from one end to a flange 13, the nozzle 14 is mounted on its axis. The conical part of the nozzle 14 with the hole 15 at its apex is inside the cylinder 9, and the cylindrical part is connected to a gas supply pipe 16 supplying gas from a cylinder (not shown in FIG. 1). The free end of the cylinder 10 by means of an adapter 17 is connected to the pipeline 5. The diameters of the cylinders 9 and 10 are 20 and 40 mm, respectively.

In the inner volume of the working chamber 7 there is a gas-air mixture distributor made in the form of metal plates 18 and 19, mounted on opposite sides to the inner surface of the housing 2, so that one edge of each plate remains free. A longer plate 18 is installed in the upper part of the working chamber and is inclined towards the radiating panel 1 by 14 °. The short plate 19 is installed closer to the panel 1 and parallel to it. The plates 18 and 19 overlap each other by a length of 15 mm. There is a gap between the plates along the height of the working chamber 7. A groove is made along the axis of the long metal plate 18 (Fig. 3), along the axis of the nozzle 6 having the shape of a segment 20 of a spherical surface, the radius of which is equal to the radius of the nozzle 6. The segment 20 is articulated with a segment 21 of the conical surface. The length of the recess is 120 mm. The larger diameter of the conical surface faces the free edge of the plate 18. The free edge of the long metal plate does not reach the body wall by 10 mm. The length of the short plate is 25 mm. In this case, a short plate overlaps the radiating perforated panel on 0.1 of its area. If the overlap of the areas exceeds 0.2, the uniformity of heating of the panel 1 is violated.

The proposed heater operates as follows. Gas from the cylinder through the pipe 16 through the nozzle 14 is supplied to the injection-mixing unit 8, where it is mixed with atmospheric air entering through the openings in the cylinders 9 and 10 of the air intake, and in the form of a stoichiometric mixture enters the working chamber. The gas-air mixture uniformly fills the working chamber, which is achieved due to the design of the plates 18 and 19, which redistribute and crush the flow of the gas-air mixture coming from the nozzle 6. During arson, the gas-air mixture burns in a thin outer layer of the emitting panel. When working on heating the road surface, the temperature on the metal mesh reaches 1000 ° and is distributed evenly over the entire radiating surface.

The design of the air intake in the form of coaxial cylinders with overlapping holes on them, as well as the removal of the injection unit outside the heater casing and its displacement relative to the center of the heater, ensures constant air leakage regardless of the position of the radiating panel and atmospheric conditions. In this case, the effect of complete flameless burning of gas and maintaining a constant temperature on the emitting surface during the entire operation of the heater is achieved. In addition, the removal of the injection-mixing unit from the heater protects it from clogging, which is inevitable when using the prototype heater in road repair conditions, and the convection of heat flows of the gas-air mixture, achieved due to the proposed design of the gas distributor, protects the housing from heating. All this allows us to consider the claimed technical result achieved.

The proposed design of a flameless infrared heater can be applied in other areas of the national economy, mainly in those cases where heating of surfaces under the heater is required.

Claims (3)

Flameless infrared heater of a pavement containing a radiating perforated ceramic panel mounted in a housing with through channels, externally covered with a refractory material mesh, an nozzle connected to a gas cylinder, and an air intake, while the fireproof radiating panel forms a working cavity with the internal cavity of the housing the chamber in which the air-gas mixture distributor is located, characterized in that the radiating panel is installed in the lower part of the housing and in the working the position is facing the road surface, the nozzle with the air intake is made in the form of a single injection-mixing unit installed outside the housing with an offset relative to its center and connected to the housing by a pipe introduced into the housing at the center of its upper surface and ending with a nozzle protruding into the working chamber, and the air-gas mixture distributor is made in the form of two metal plates of different lengths, fastened along the contour with the inner surface of the housing from opposite sides the free edges of the plates are one above the other, approaching one after another in length, and overlapping the working chamber by its cross-sectional area, the short metal plate being installed closer to the radiating perforated panel, the long metal plate is inclined towards the radiating perforated panel, while between There are gaps on the long metal plate and the pipe on one side and a short metal plate on the other side, and a recess is made along the axis of the long metal plate, about the axis of the nozzle having the shape of a segment of a spherical surface, the radius of which is equal to the radius of the nozzle articulated with a segment of the conical surface, with a large diameter facing the free edge of a long metal plate. 2. The heater according to claim 1, characterized in that the air intake is made in the form of two coaxial hollow cylinders of different lengths, a short cylinder of a smaller diameter has through perforation, through a long cylinder of a larger diameter, through slots are made along its generatrix along the perforation length of the short cylinder, both cylinders at one end they are connected by a flange along the axis of which a nozzle is installed, the conical part of which with the gas outlet for the outlet of gas at the top of the cone is inside a short cylinder of smaller diameter, and The second part is connected to the pipeline, a supply gas from the cylinder, while the free end of the larger diameter cylinder is connected to a line for supplying the air-gas mixture. 3. The heater according to claim 1, characterized in that the short plate covers the radiating perforated panel by no more than 0.2 of its area.

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