RU168562U1 - Hot water boiler - Google Patents

Abstract

The utility model relates to the field of small heat power engineering, in particular, to designs of hot water boilers designed for heating residential premises and buildings with an area of up to 120 m and a volume of 360 m, as well as for producing hot water for domestic needs. The hot water boiler contains a vertical cylindrical body in the cavity of which the convective part, the smoke exhaust pipe and the furnace, are arranged in the form of a vertically oriented spiral pipe coaxial with the body, the turns of which are tightly closed, while the boiler is equipped with pipes for water and water drainage. The convective part is made in the form of spiral lattices coaxial with the furnace, the external of which covers the inner, while the external spiral lattice has a gap with both the casing and the internal spiral lattice, which, in turn, has a gap with the furnace, and the turns of the spiral lattices constitute a gap with each other, corresponding to the diameter of the pipes used to form the spiral gratings. The upper end of the furnace is covered by a lid, and in its cavity, coaxially with it and with a gap, a flameless gas burner is placed. The boiler outlet pipe is in communication with the upper turn of the spiral pipe forming the firebox, the lower turn of which is in communication with the lower turn of the internal spiral grate, the upper turn of which is in communication with the upper turn of the external spiral grate, the lower turn of which is in communication with the water supply pipe. The housing is equipped with a removable conical cover, the upper edge of which is equipped with a flue pipe, in addition, the lower part of the housing is equipped with a supporting transverse frame made with the possibility of supporting the firebox and spiral gratings on it, below which is made

Description

The utility model relates to the field of small heat power engineering, in particular, to the designs of hot water boilers designed for heating residential premises and buildings with an area of up to 120 m ² and a volume of 360 m ³ , as well as for producing hot water for domestic needs.

A heating apparatus is known, comprising a cylindrical body in the form of a water jacket framing a cylindrical firebox, which is connected to the gas outlet by means of smoke tubes that act as a convective gas duct, while the smoke tubes are equipped with flap turbulators, moreover, in the water volume between the walls of the furnace and the body is placed a coil for producing hot water (see ACGV - 17.4 -1; TU-929-31-91, drawing. 4462СБ). The lining of the device is made in the form of a parallelepiped. Fuel is natural gas.

The disadvantages are the lack of thermal performance of the boiler, its metal consumption, intensive drift of smoke pipes by the combustion products, which leads to a weakening of heat transfer and reduce the efficiency of the apparatus.

A boiler is also known, which contains a vertical cylindrical body, in the cavity of which there is a convective part, a smoke outlet and a firebox made in the form of a vertically oriented spiral pipe, coaxial with the body, the turns of which are tightly closed, while the boiler is equipped with water inlet and outlet pipes (see . RU No. 2419040, IPC F24H1 / 43, 2010).

The disadvantages of this solution are the insufficient heat output of the boiler, insufficient use of the heat of the burned fuel, and its structural complexity.

The task to which the claimed technical solution is directed is expressed in reducing the material consumption of the boiler, increasing its heat output and the full use of the heat of the burned fuel.

The technical result obtained when solving the problem is expressed in reducing the material consumption of the boiler (boiler dimensions of 15 kW are 570 mm in height and diameter 285 mm in the flange); increasing its heat output (due to the use of a flameless gas burner) and the full use of the heat of the burned fuel (due to the efficient utilization of the heat of the exhaust gases).

To solve this problem, the boiler is a hot-water boiler containing a vertical cylindrical body, in the cavity of which there is a convective part, a smoke outlet and a furnace made in the form of a vertically oriented spiral pipe, coaxial with the body, the turns of which are tightly closed, while the boiler is equipped with water inlet and outlet pipes , characterized in that the convective part is made in the form of spiral lattices coaxial with the furnace, the outer of which covers the inner, while the outer spiral lattice has a gap with housing and with an internal spiral grill, which, in turn, has a gap with the furnace, and the turns of spiral lattices make up a gap with each other, corresponding to the diameter of the pipes used to form the spiral lattices, in addition, the upper end of the furnace is covered with a lid, and in it a cavity, coaxial with it and with a gap, a flameless gas burner is placed, in addition, the boiler outlet pipe is in communication with the upper turn of the spiral pipe forming the firebox, the lower turn of which is in communication with the lower turn of the internal spiral grate, the upper turn of which is in communication with the upper turn of the external spiral grate, the lower turn of which is in communication with the water supply pipe, in addition, the housing is equipped with a removable conical cover, the upper edge of which is equipped with a smoke exhaust pipe, in addition, the lower part of the housing is equipped with a supporting transverse frame made with the possibility of supporting the firebox and spiral gratings on it, below which a support platform for a flameless gas burner is made. In addition, the vertical cylindrical body of the boiler is equipped with vertical supports. In addition, the flameless gas burner includes a perforated tubular housing configured to communicate with a gas source, air supply means, and the perforated tubular housing is placed coaxially in the cavity of the porous nozzle, made in the form of a cylindrical glass made of porous heat-resistant material. In addition, the porous nozzles are made of porous ceramic material.

A comparative analysis of the features of the claimed solution with the signs of the prototype and analogues indicates the conformity of the claimed solution to the criterion of "novelty."

The combination of features of the distinctive part of the utility model formula provides a solution to the technical problem posed, namely, reducing the material consumption of the boiler, increasing its heat output and the full use of the heat of the burned fuel.

The claimed device is illustrated by drawings, where figure 1 shows a vertical longitudinal section of the boiler (burner not shown); figure 2 shows a vertical longitudinal section of a boiler with a burner; figure 3 shows a top view of the boiler, figure 4 shows the appearance of the boiler in volume.

The drawings show the cylindrical body 1 of the boiler, its cavity 2, furnace 3, nozzles for supplying 4 and water outlet 5, external 6 and internal 7 spiral grids, gaps 8 of spiral grids, with each other, body 1 and furnace 3, gaps 9 between turns spiral grids 6 and 7, top end 10 of furnace 3, cover 11, cavity 12 of furnace 3, flameless gas burner 13, removable conical cover 14, smoke exhaust pipe 15, supporting cross frame 16, supporting platform 17 for flameless gas burner 13, vertical supports 18, the longitudinal axis 19 of the boiler body 1. In addition, elements of a flameless gas burner 13 are shown — a perforated tubular body 20, a gas source 21, air supply means 22, and porous nozzles 23.

The hot water boiler contains a vertical cylindrical body 1, in the cavity 2 of which the convective part and the furnace 3 are placed. The furnace 3 is made in the form of a vertically oriented spiral pipe, coaxial with the body 1, the turns of which are tightly closed, forming a gas-tight wall. The boiler is equipped with nozzles for supply 4 and outlet 5 for water.

The convection part of the boiler contains spiral coaxial coaxial with the furnace 3, the outer 6 of which covers the inner 7, while the external spiral lattice 6 has gaps 8 with both the casing 1 and the internal spiral lattice 7, which, in turn, has a gap 8 with the furnace 3, and the coils of the spiral grids 6 and 7 constitute a gap 9 with each other, corresponding to the diameter of the pipes used to form the spiral grids 6 and 7. To attach the spiral grids 6 and 7, it is possible to weld “ears” with clamps in the cavity 2 of the housing 1 (on drawings not shown).

The top end 10 of the furnace 3 is hermetically closed by a cover 11, and in its cavity 12, coaxially with it and with a gap, a flameless gas burner 13 is placed. The outlet pipe 5 of the boiler is in communication with the upper turn of the spiral pipe forming the furnace 3, the lower turn of which is connected with the lower a turn of the internal spiral lattice 7, the upper turn of which is in communication with the upper turn of the external spiral lattice 6, the lower turn of which is in communication with the pipe for supplying 4 water.

The housing 1 is equipped with a removable conical cover 14, the upper edge of which is provided with a flue pipe 15, in addition, the lower part of the housing 1 is equipped with a supporting transverse frame 16, made with the possibility of supporting the firebox 3 and spiral gratings 6 and 7. A supporting platform is made below the frame 16 17 for a flameless gas burner 13. In addition, the vertical cylindrical body of the boiler is equipped with vertical supports 18.

Flameless gas burner 13 contains a perforated tubular body 20, configured to communicate with a gas source 21, air supply means 22, while the perforated tubular body 20 is placed coaxially in the cavity of the porous nozzle 23, made in the form of a cylindrical glass made of porous heat-resistant material, for example, porous ceramic material.

It is preferable to use a flameless gas burner of the type developed by the Tomsk Scientific Center SB RAS, with a porous nozzle 23 made of porous ceramics based on metal oxides, with an open porosity of 60-70% (see RU No. 2310129, F23D14 / 12, 2007 ) Tests on the same type of gas water-heating boilers showed that with the same boiler performance, the fuel economy in a boiler with a burner, on which a ceramic nozzle is mounted, is 10-30%, depending on the load.

The claimed boiler operates as follows.

Water with a temperature of 40-800 ° C is used as a heat carrier. It is led through the wall of the housing 1 into the lower turn of the external spiral grate 6, rising through which water enters the upper turn of the internal spiral grating 7 and then falls along it and enters the lower turn of the furnace 3, rises along the turns of the furnace and leaves through the water outlet 5 held through the cover 14 of the housing 1.

In the burner, a mixture of combustible gas (supplied from a gas source 21 through a perforated tubular body 20) is mixed with air (supplied by an air supply means 22), and the gas-air mixture enters the porous ceramic nozzle 23. The gas mixture is filtered through the porous walls of the nozzle, comes to the surface and ignited by a pilot light (not shown in the drawings). The surface of the furnace 3 is heated by a surface flame to 1000-1100 ° C. Thermal radiation from the surface of the nozzle heats the water located in the spiral tube of the furnace.

From the heated surface of the nozzle, its wall warms inward. In order to avoid ignition of gas inside the nozzle, the temperature should not be higher than the ignition temperature (not more than 500 ° C). Filtration provides fire protection and heating of the combustible mixture

Since the upper end of the furnace is hermetically closed by the cover 11, the combustion products are lowered in the gap between the furnace 3 and the ceramic nozzle 23, washing the pipes that make up the furnace, giving them heat and water filling them. Further, the combustion products rise upward in the gap between the wall of the housing 1 and the outer wall of the furnace 3 (in the convective part of the boiler), where the remaining heat is transferred to the spiral gratings 6 and 7, warming up the water in them, thereby pre-heating it before it enters spiral furnace tube 3.

The cover 14 of the housing 1 provides the collection of flue gases and their removal into the flue pipe 15.

Claims (4)

1. The boiler is a hot water boiler containing a vertical cylindrical body, in the cavity of which there is a convective part, a flue pipe and a furnace made in the form of a vertically oriented spiral pipe, coaxial with the body, the turns of which are tightly closed, while the boiler is equipped with water inlet and outlet pipes, different the fact that the convective part is made in the form of spiral lattices coaxial with the furnace, the external of which covers the internal, while the external spiral lattice has a gap with both the body and the internal spiral lattice, which, in turn, has a gap with the firebox, and the turns of spiral gratings make up a gap with each other, corresponding to the diameter of the pipes used to form the spiral gratings, in addition, the upper end of the firebox is covered by a lid, and in its cavity, coaxially with with a gap, a flameless gas burner is placed, in addition, the boiler outlet pipe is in communication with the upper turn of the spiral pipe forming the firebox, the lower turn of which is in communication with the lower turn of the internal spiral grate, the upper turn of which is communicated the upper turn of the external spiral lattice, the lower turn of which is in communication with the water supply pipe, in addition, the casing is equipped with a removable conical cover, the upper edge of which is equipped with a flue pipe, in addition, the lower part of the casing is equipped with a supporting transverse frame made with the possibility of supporting the firebox on it and spiral gratings, below which a support platform for a flameless gas burner is made. 2. The hot water boiler according to claim 1, characterized in that the vertical cylindrical body of the boiler is equipped with vertical supports. 3. The hot water boiler according to claim 1, characterized in that the flameless gas burner comprises a perforated tubular body configured to communicate with a gas source, air supply means, wherein the perforated tubular body is placed coaxially in the cavity of the porous nozzle made in the form of a cylindrical glass from porous heat-resistant material. 4. The boiler according to claim 1, characterized in that the porous nozzles are made of porous ceramic material.

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