RU130672U1 - CHIMNEY DRAINAGE THROTTLE STABILIZER EQUIPPED WITH EXPLOSIVE VALVES - Google Patents

Abstract

1. The chimney draft throttle stabilizer, characterized in that it contains a housing having rigidly fixed lower, upper and rear surfaces, the side surfaces of the housing are cover plates made with the possibility of their movement relative to the housing, a throttle in the form of a rectangle is located on the front surface of the housing made with the possibility of rotation relative to the axis of symmetry located along the axis of symmetry of the damper and mounted on the housing, while the axis of rotation of the dros The damper is the upper front edge of the casing, the rear surface of the casing is equipped with a rigidly mounted, surface-mounted flange for attaching to the chimney or flue. 2. The stabilizer according to claim 1, characterized in that the casing is made of sheet stainless steel or stainless steel. The stabilizer according to claim 1, characterized in that the housing contains a frame of metal profiles. The stabilizer according to claim 1, characterized in that the overhead covers are arranged to move relative to the housing in planes parallel to them. The stabilizer according to claim 4, characterized in that the overhead covers are connected to the housing by means of studs equipped with a spring-return mechanism. The stabilizer according to claim 1, characterized in that the overhead covers are made to rotate relative to the housing. The stabilizer according to claim 6, characterized in that the overhead covers are connected to the upper part of the housing by means of hinges. The stabilizer according to claim 4 or 6, characterized in that the overhead covers are made in the form of rectangular plates made of stainless steel

Description

The utility model relates to a chimney draft choke stabilizer equipped with explosive valves. The chimney draft throttle stabilizer can be used in any boiler plants and power plants, the principle of operation of which is based on the receipt of thermal (or electric) energy due to fuel combustion, in which the chimney serves as an exhaust fan in the combustion product removal system.

Currently known solutions to various devices used to stabilize the pressure in the chimneys.

So, from the description of the patent of the Russian Federation No. 2118283 (published on 08.27.1998), a lightweight explosive valve is known, in particular for pipelines, to equalize pressure surges during possible dust or gas explosions in closed systems, such as elevators, pipelines and the like, with a rotating around the swing axis on the outlet pipe a hinged lid, which is at least in a limited area made in the form of a hollow body, while the hinged lid has a flat outer surface, and located against the outer surface, the inner surface of the hinged lid directed to the inner cavity of the exhaust pipe is convex, and the walls forming the hinged lid are made of thin metal sheets.

A disadvantage of the known explosive valve is that the known explosive valve is not a stabilizer and is intended only to equalize positive pressure surges during possible explosions of dust or gas exclusively in closed systems, such as elevators, pipelines or the like.

In addition, an automatic draft stabilizer is known which comprises a valve of aluminum or a similar sheet mounted rotatably on an axis. The sides of the sheet are made with flanges and transverse grooves located asymmetrically and with a longitudinal slot for the load and the lever (UK patent No. 683896, published 10.12.1952).

This technical solution is equipped with one single valve (damper), designed simultaneously to control both excess positive and excess negative pressure. Such a design, due to the inertia of the extreme valve actuation positions, cannot provide stabilization of the flame on the burner device at the time of sudden changes in the pressure in the chimney from a positive value to a negative value, and vice versa. Such a situation is possible with a strong wind changing its direction. In addition, the design features of this technical solution (visual confirmation - “obturator plate”) significantly reduce the opening angle of the valve, which greatly reduces the maximum value of the device’s performance to limit vacuum in the smoke exhaust system, which is unacceptable for using this solution in smoke removal systems of powerful boiler plants ( from 200 kW and more). This invention is not equipped with a system for damping sharp jerks of a valve (damper) arising from sudden changes in pressure characteristic of smoke exhaust systems of powerful boiler plants. The absence of damping systems for sharp jerking of the valve (damper), under the conditions of operation of this device in industrial boiler plants, will inevitably lead to its rapid self-destruction, which is a significant design flaw.

The closest analogue to the solution being tested is a draft stabilizer, known from German patent No. 19511577 (published 02.11.1995), made in the form of a housing with a damper fixed on an axis mounted for rotation on the upper part of the housing, which closes the outlet of the flue gas stream.

The objectives of the disclosed design is to optimize chimney draft exclusively for households and / or small enterprises equipped with individual low-power heating systems. The design features of this solution (visual confirmation - “locking plate”) are the limited valve opening angle, which is unacceptable for using this solution in smoke removal systems of powerful boiler plants (from 200 kW and more). This utility model is also not equipped with a damping system for sudden valve jerks (flaps) arising from sudden changes in pressure characteristic of smoke exhaust systems of powerful boiler plants. The absence of damping systems for sharp jerking of the valve (damper), under the conditions of operation of this device in industrial boiler plants, will inevitably lead to its rapid self-destruction.

In addition, the disadvantage and significant difference of the design disclosed in German patent No. 19511577 is that this technical solution is not equipped with explosive valves, which eliminate excess positive pressure, unlike DSTD-VK.

The technical result of the patented solution is to ensure the stabilization of draft (vacuum) in the smoke exhaust system of boiler complexes at a value as close as possible to that specified by the boiler manufacturer by eliminating sudden pressure surges: compensation of excess negative pressure is carried out by opening the throttle gas (combustion products) with excess negative pressure. dampers inside the device and dosed air from the boiler room, and the elimination of sudden surges is excessive th positive pressure - due to excessive opening of the positive pressure gas (combustion) side covers overhead (explosive valves) of the device outwardly and bleed the excess positive pressure. Sudden pressure surges can occur as a result of Zhukovsky’s “Water hammer” in smoke exhaust systems. The above method eliminates pressure fluctuations in the smoke exhaust system resulting from seasonal climatic changes. The result of stabilization of the draft is to increase the effective life of the boiler equipment by stabilizing the shape of the flame on the burner, as excessive draft changes (extends) the shape of the torch, and the fire directly contacts the surface of the cast-iron sections of the boiler. Also, the technical result is the saving of fuel resources by reducing heat loss with exhaust flue gases. Excessive draft increases the flow of air passing through the combustion chamber. The entire volume of excess air that is not involved in the combustion process is heated to high temperatures and released into the atmosphere. When reducing heat losses with flue gases, less fuel is required to produce the same specified amount of heat. Thus, the stabilization of the draft in the smoke exhaust system (avoiding excessive negative pressure) will lead to savings in fuel resources of boiler plants.

The claimed technical result is achieved due to the design of the throttle stabilizer of the chimney draft, comprising a housing having rigidly fixed lower, upper and rear surfaces; the side surfaces of the housing are patch covers, made with the possibility of their movement relative to the housing; on the front surface of the housing there is a throttle in the form of a rectangle, made to rotate relative to the axis of symmetry located along the axis of symmetry of the valve and mounted on the housing, while the axis of rotation of the throttle is the upper front edge of the housing; the back surface of the body is equipped with a rigidly fixed patch flange for attaching to a chimney or gas duct.

The housing may contain a frame of metal profiles.

In this case, the housing, covers and throttle can be made of sheet stainless steel or corrosion-resistant steel.

Cover caps have a rectangular shape, can be made in the form of plates of stainless steel or stainless steel and perform the function of explosive valves.

Overhead covers are made with the possibility of their movement relative to the housing in planes parallel to them and are connected to the housing by means of studs equipped with a spring mechanism.

In addition, overhead covers can be made with the possibility of opening them outward by rotation relative to the housing due to their connection with the upper part of the frame by means of hinges.

In particular, the housing may be in the form of a cube.

The throttle is a rectangle that is divided into two parts by the axis of rotation. The area of the rectangle is selected no more than the total area of the two surfaces of the cube, and stands up to the perimeter of the front surface of the casing. In this case, the axis of rotation of the throttle valve is the upper front edge of the housing (or frame). The damper is inserted inside the device and fastened by the axis of rotation to the device. The axis of rotation of the throttle is the upper front edge of the stabilizer body. The lower part of the shutter is located inside the device, the upper part of the shutter is above the suspension axis, located outside the device. The throttle valve opens into the instrument.

The damper is equipped with a pulse absorber, attached on one side to the outer part of the throttle, and on the other hand, on the upper surface of the stabilizer housing, which makes it possible to use the device in smoke exhaust systems of powerful industrial boiler complexes. The pulse damper can be a hydraulic piston pulse damper, pneumatic or hydropneumatic pulse damper can also be used.

To provide an effective solution to the problem of excess negative pressure, the throttle can additionally be equipped with performance regulators.

The patch flange has a through hole of a circular shape, the diameter of which is equal to a circle inscribed in a rectangle on the back of the case.

The stabilizer patch flange is attached (welded) externally to the back of the instrument. The flange can be equipped with slots (longitudinal holes) for mounting and centering the mount of the stabilizer.

The dimensions and performance of the device are calculated based on the parameters of the systems for removing combustion products and boiler equipment.

A specific embodiment of a patentable utility model is shown in the figures.

The figure 1 shows a stabilizer, the side covers of which are connected to the housing through loops;

In figure 2 - stabilizer, the side covers of which are connected to the housing by means of studs equipped with a spring mechanism;

Figure 3 is a graph of the dependence of heat loss with flue gases (q _A ) on the draft in smoke removal systems.

The stabilizer shown in figure 1 contains a housing 1, a throttle valve 2, a regulator 3 for fine tuning the performance of the throttle valve, a regulator 4 for the performance of the throttle valve, the fastening 5 of the hydraulic damper to the throttle valve (for example, an arm, not shown in the figure), hydropneumatic damper 6, bracket 7 for mounting the hydropneumatic damper 6 to the upper surface of the stabilizer body, upper surface 8, patch flange 9, hinge 10 fastenings dnyh covers the upper surface of the housing, overhead cover 11, a bottom surface 12, the throttle valve axis 13.

The stabilizer shown in figure 2 also contains the stabilizer of figure 1, the housing 14, the throttle valve 15, the regulator 16 fine tuning the performance of the throttle valve, the regulator 17 of the performance of the throttle valve, attaching the 18 hydraulic damper to the throttle valve (by, for example , bracket, not shown in the figure), a hydropneumatic damper 19, a bracket 20 for mounting a hydropneumatic damper 19 to the upper surface of the stabilizer body, the upper surface 21, patch flange 22, four pairs of studs 23 with springs (spring-return mechanism 24), nuts 25, washers 26, patch caps 27, bottom surface 28, throttle axis 29.

The stabilizer is mounted by welding or by bolting to a chimney or gas duct inside the boiler room, and works as follows.

In the event of excessive positive pressure in the chimney, the overhead covers (explosive valves) either open upward outward, making a rotational movement relative to the body through hinges, or open outward, moving in a plane parallel to them along the hairpins.

When the excess positive pressure disappears, the overhead covers are closed either due to gravity (in the case of fastening them with hinges, Fig. 1), or due to the spring-return mechanism (in the case of fastening on studs).

The hydraulic damper is attached to the throttle by means of an arm similar in design to the bracket for attaching the hydraulic damper to the top cover of the device.

The throttle valve maintains a negative constant pressure in the smoke exhaust system. The throttle valve is located on the outside of the device attached to the chimney (or flue), and is located on the border between the negative value of the pressure in the chimney cavity and the “neutral” (conditionally atmospheric) pressure in the boiler room. The “value” set by the device performance regulators corresponds to the value of negative pressure (vacuum) at the boiler nozzle recommended by the boiler manufacturer. With an increase in negative pressure (increase in negative pressure), the damper opens inward, letting in air from the boiler room, thereby reducing the negative pressure to a parameter specified by the device settings.

Throttle performance controller - designed for factory settings of the valve. The regulator for fine tuning the performance of the throttle valve sets a value that ensures a vacuum on the chimney pipe of the boiler that meets the recommendations of the manufacturer of boiler equipment (boilers).

For complete combustion, the fuel entering the burner of the boiler requires a certain amount of oxygen (air). Excessively high vacuum on the boiler nozzle creates an influx of excess (not involved in the combustion process) air, which leads to heat loss that occurs with the emission of flue gases into the atmosphere (heat loss with flue gases). Fuel consumption in boiler complexes is saved by reducing heat loss by reducing the coefficient (quantity) of excess air that is not involved in the combustion process.

Theoretical calculations based on the dependence of heat loss (respectively, fuel overhead while maintaining specified heat output values) on the temperature difference between flue gases and atmospheric air, and the applicable standards for the design of smoke removal systems for boiler complexes, showed that stabilization of the discharge (draft) on the boiler nozzle within the values close to the parameters set by the boiler manufacturer, it gives a positive economic effect - saving fuel resources. The amount of savings depends on the power of the boiler, the parameters of the smoke exhaust system (diameter and length of the flue, chimney, diameter and height of the chimney, etc.) and weather conditions (air temperature, the magnitude of the differences in day and night temperatures, etc.) in which the boiler complex is operated.

Calculation of heat loss occurring with the emission of flue gases into the atmosphere is performed as follows (based on Siegert's formulas):

Formula using carbon dioxide (CO ₂ ) indicators in chimney gases, in percent.

A formula that uses oxygen (O ₂ ) in chimney gases, in percent.

q _A Flue gas heat loss, [%] θ _A Flue gas temperature [° С] θ _L  Air temperature supplied to the burner, [° С] A1, A2, B calculation factors by type of fuel (Siegert) Natural gas Propane Diesel A1 0.37 0.42 0.50 A2 0.66 0.63 0.68 AT 0.009 0.008 0.007

The actual efficiency of boilers (boiler rooms and thermal power plants) is equal to 100%

Carbon dioxide (CO ₂ ), oxygen (O ₂ ) and other gases contained in the flue gases are measured by flue gas analyzers, such as the Testo 330 Flue Gas Analysis System (www.testo.ru) and other instruments certified in Of Russia.

As can be seen from the graph shown in figure 3, the percentage of carbon dioxide (CO ₂ ) and oxygen (O ₂ ) is inversely proportional, and the percentage of one or another test gas shows the value of heat loss with flue gases (q _A ) .

It can also be seen from the graph that the value of f ”increases with increasing coefficient of excess air, i.e. with an increase in the volume of air passing through the burner device of the boiler. The increase in the volume of air passing through the burner and the cavity of the boiler is directly related to the increase in draft of the chimney.

Thus, as follows from the graph, with an increase in excess draft in the smoke exhaust system, the coefficient of excess air increases and losses with exhaust flue gases increase (q _A ).

Optimization of draft (reduction of excess draft) in the smoke exhaust system reduces losses with flue gases, and, accordingly, the excessive consumption of fuel while maintaining the set values of the heating capacity of the boiler complex.

The design features of the patented stabilizer are:

- An original and technically safe solution to the problem of “Zhukovsky’s water hammer” arising in combustion products removal systems (in flues and chimneys) - a rapid change in the gas (combustion products) flow rate in a pipe over a short period of time leads to a sharp pressure jump. When the boiler starts up, positive pressure surges cause a pop or explosion. In case of a sudden shutdown of the burner device (quick closing of the air valve, technical defect or power failure), surges of negative pressure destroy (crush inward) the elements of smoke exhaust systems and can lead to damage to the boiler equipment.

- Explosive valves (patch caps) - repeated action, the design of which is effective and technically safe.

- The proposed constructive solution of the stabilizer allows you to effectively solve simultaneously the problems of excess positive and excess negative pressure in the systems of removal of combustion products (in flues and chimneys).

- Stabilizers can be of various sizes and different capacities depending on the parameters of smoke exhaust systems and the power of boiler equipment, and can be used in industrial boiler plants and power plants, the principle of which is based on the generation of energy from fuel combustion, in which the chimney serves as an exhaust fan in the system of removal of combustion products.

Claims (16)

1. The chimney draft throttle stabilizer, characterized in that it contains a housing having rigidly fixed lower, upper and rear surfaces, the side surfaces of the housing are cover plates made with the possibility of their movement relative to the housing, a throttle in the form of a rectangle is located on the front surface of the housing made with the possibility of rotation relative to the axis of symmetry located along the axis of symmetry of the damper and mounted on the housing, while the axis of rotation of the dros The damper is the upper front edge of the casing, the rear surface of the casing is equipped with a rigidly mounted, surface-mounted flange for attaching to the chimney or flue. 2. The stabilizer according to claim 1, characterized in that the casing is made of sheet stainless steel or stainless steel. 3. The stabilizer according to claim 1, characterized in that the housing contains a frame of metal profiles. 4. The stabilizer according to claim 1, characterized in that the overhead covers are arranged to move relative to the housing in planes parallel to them. 5. The stabilizer according to claim 4, characterized in that the overhead covers are connected to the housing by means of studs equipped with a spring-return mechanism. 6. The stabilizer according to claim 1, characterized in that the overhead covers are made to rotate relative to the housing. 7. The stabilizer according to claim 6, characterized in that the overhead covers are connected to the upper part of the housing by means of hinges. 8. The stabilizer according to claim 4 or 6, characterized in that the overhead covers are made in the form of rectangular plates made of stainless steel or stainless steel. 9. The stabilizer according to claim 1, characterized in that the throttle is made of sheet stainless steel or stainless steel. 10. The stabilizer according to claim 1, characterized in that the casing is in the form of a cube. 11. The stabilizer according to claim 9, characterized in that the throttle valve is a rectangle, the area of which is selected no more than the total area of the two surfaces of the cube, and protrudes beyond the perimeter of the front surface of the casing. 12. The stabilizer according to claim 1, characterized in that the axis of rotation of the throttle valve coincides with the upper front edge of the housing. 13. The stabilizer according to claim 9 or 11, characterized in that the throttle valve is equipped with a pulse damper attached on one side to the outer part of the throttle valve, and on the other hand, to the upper surface of the housing. 14. The stabilizer according to item 13, characterized in that the pulse damper is a piston pulse damper, which can be hydraulic, or pneumatic, or hydropneumatic damper. 15. The stabilizer according to claim 1, characterized in that the patch flange has a through hole of circular shape, the diameter of which is equal to a circle inscribed in the rectangle of the side of the housing. 16. The stabilizer according to claim 1, characterized in that the patch flange is equipped with slots for mounting and alignment of the mounting at the connection point of the device.

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