UA118651U - BOILER - Google Patents

Abstract

The boiler contains a furnace with a burner, a combustion chamber that is connected to the gas duct, and part of the wall of the duct has a zone of heat transfer from the gaseous combustion products to the liquid. The above pipeline heat transfer zone has at least one main heat exchange area and at least one additional heat exchange area. The auxiliary heat exchange section comprises at least one auxiliary heat exchange pipe intersecting the duct and the inner space of which is connected to the inner space of the aforementioned circumferential passage for fluid passage. The screens of the peripheral flow distribution are coaxial to the gas duct and have the appearance of transverse partitions, which are made in such a way as to have the outline of the cross section of the duct, and form slit openings along the inner surface of the duct, and the specified screen of the central distribution of the gas flow coexistence has the appearance of a cross-section, which along the periphery has a solid connection with the inner surface of the gas duct and contains in the central part of the hole for the passage of gaseous x combustion products. The duct formed in the duct for the passage of the stream of gaseous combustion products has a cross-sectional area not less than the area of the duct outlet located after the latter in the direction of the combustion products stream of the peripheral flow distribution screen or the last of the above-mentioned at least one additional heat exchange pipe.

Description

The useful model belongs to thermal power engineering, in particular to means of heat exchange between gaseous combustion products and heating liquids through a wall separating these heat carriers, and can be used in heating devices used in heating systems of domestic, commercial, industrial and other premises. as well as for heating water in the hot water supply system.

From the state of the art, the principle of building heat exchange devices according to the so-called "pipe-in-pipe" principle is known, which, in particular, is disclosed in DSTU EM 247:2003. This principle provides such a design of heat exchange devices, in which heat exchange is carried out between two heat carriers, physically separated from each other by a wall. At the same time, both coolants flow in parallel directions, one coolant flows through an internal channel formed by one pipe, and the other in a belting channel formed by a second pipe located coaxially around the first pipe. The specified principle of heat exchange is used, in particular, in the main heat exchange parts of solid fuel boilers, and additional devices of these boilers, such as recuperators or economizers. Such devices transfer heat from gaseous combustion products to a liquid, where the flow of gaseous combustion products moves through the central channel and through the wall transfers heat to the liquid moving in the outer, surrounding, belting channel.

Thus, the application of the above-described principle is known, for example, in the design of the solid-fuel boiler "Teplotron "Mini" (per/Leriotop.5y/rgodisiop/5/19/), the scheme of which provides for the formation of a "shirt" with a liquid coolant around the fuel combustion zone and gas duct. This solution is inefficient, taking into account the small contact surface of the coolants, which is located mainly around the combustion zone and the location of solid fuel.

The technical solution of the boiler design is also known, which is disclosed in the description of the water-heating boiler before the invention according to the author's certificate of the USSR Mo 365533 (МПК: Е24НО1/24, publ. 01.08.1973).

According to the specified description, the boiler has a wall that separates the solid fuel combustion zone and the gas duct from the water channel, which covers the specified zones and is designed as a "water jacket".

A significant part of the total wall surface through which heat is transferred is the gas duct itself. It is the heat exchange part of the indicated boiler, which includes the gas pipe, that completely reproduces the above scheme and implements the principle of the heat exchanger "pipe in a pipe". In this case

The gas duct, into which the gaseous combustion products are directed, and the circumferential channel, into which the heating liquid is directed, are coaxial and have a circular cross-section.

The described solution is very simple and quite effective. However, it has a significant drawback. It is clear that the process of obtaining a heated liquid or steam must have an appropriate performance. To ensure the required productivity, the above-mentioned wall through which heat is transferred, or more precisely, the contact zone of the coolants, must have a certain area.

Increasing the productivity of obtaining heated liquid or steam, in particular, can be achieved by changing the design of the heat exchange part, which involves increasing the contact surface of gaseous combustion products and liquid. Such an increase in the contact surface can be achieved by increasing the length of the corresponding channels or increasing the cross-sectional area of these channels, which is unacceptable in many cases.

It is known that heat transfer by convection consists in the transfer of heat by moving the particles of gaseous combustion products themselves, and it is accompanied by heat conduction, that is, the transfer of heat from one particle to another. When the area of the above-mentioned cross-sections of the channels increases, the cross-section of the flow of gaseous combustion products increases and, accordingly, the distance between the heat-carrying particles located in the central part of the flow and the wall through which heat is transferred to the liquid increases. In this way, the efficiency of heat transfer decreases, part of the heat is simply lost together with particles of gaseous combustion products emitted through the chimney.

Taking into account the above, there is an urgent need to increase the efficiency of heat transfer from gaseous combustion products through the wall to the liquid without changing the cross-section of the heat exchange wall of the gas duct, the overall dimensions of the heat exchange part of the gas duct, the temperature and volume of gaseous products obtained during fuel combustion and the mode of liquid supply , which heats up.

The task of a useful model is to create a design of a boiler for obtaining steam or heating a liquid, in which heat is transferred from gaseous combustion products to the liquid through the wall, with a higher efficiency of heat transfer without changing the cross-section of the heat exchange wall of the gas duct and its overall dimensions, temperature and volume it contains gaseous products obtained during the combustion of fuel and the heating liquid supply mode.

At the same time, a boiler is understood as a device in which the heat released during the combustion of organic fuel is used to generate steam or heat a liquid under pressure above atmospheric, which is consumed outside the limits of this device. And not only water, but also other liquid coolants are considered as a liquid that is heated, or from which steam is obtained.

As the closest analog to the claimed useful model, the design of the boiler, which is given in the description of the invention according to the author's certificate of the USSR Mo 365533, was chosen.

Common features of the declared design solution of the boiler and the closest analogue are the following features: - the presence of a furnace with a burner, a combustion chamber of the furnace, which is connected to the gas duct; - the presence of a heat transfer zone from gaseous combustion products to liquid in part of the gas duct wall, where these gaseous combustion products are in contact with the inner surface of the wall, and the liquid is in contact with the outer surface of the wall; - the specified part of the gas duct wall, which forms the heat transfer zone, separates the channel for the passage of the flow of gaseous combustion products and the coaxial belting channel for the passage of the heating liquid.

The problem is solved by the fact that in a boiler that has a furnace with a burner, the combustion chamber of the furnace is connected to the flue, and part of the flue wall has a zone of heat transfer from gaseous combustion products to the liquid, where these gaseous combustion products are in contact with the inner surface of the flue wall , and the liquid is in contact with the outer surface of the gas duct wall, i.e., the specified part of the gas duct wall, which forms the heat transfer zone, separates the channel for the passage of the flow of gaseous combustion products and the coaxial belting channel for the passage of the heating liquid, according to the useful model, the above transfer zone the heat pipe has at least one section of the main heat exchange and at least one section of additional heat exchange.

The specified section of the main heat exchange is formed by at least two consecutively installed screens for the peripheral distribution of the flow of gaseous combustion products. And the specified area of additional heat exchange is formed by one peripheral flow distribution screen and one central flow distribution screen of gaseous combustion products or

With one peripheral flow distribution screen and gas duct outlet.

The above section of additional heat exchange contains at least one pipe of additional heat exchange crossing the gas duct, and the inner space of which is connected to the inner space of the above belted channel for the passage of liquid.

The specified peripheral flow distribution screens are coaxial with the gas duct and have the form of transverse partitions, which are made in such a way that they have an outline similar to the outline of the cross section of the gas duct, and form slit-like openings along the inner surface of the gas duct.

The specified screen for the central distribution of the flow of gaseous combustion products is coaxial with the flue and has the form of a transverse partition, which on the periphery has a continuous connection with the inner surface of the flue and contains in the central part an opening for the passage of gaseous combustion products.

All the above-described additional heat exchange pipes, peripheral flow distribution screens, and central flow distribution screens are made and placed in such a way that the channel formed in the gas duct for the flow of gaseous combustion products has a cross-sectional area not less than the area of the outlet opening of the gas duct.

The above-mentioned exit hole of the gas duct is located after the last in the direction of the flow of combustion products of the peripheral flow distribution screen or the last above-mentioned at least one pipe of additional heat exchange.

In some cases, the implementation of the declared boiler design solution, the above-mentioned peripheral flow distribution screens and central flow distribution screens can be made in the form of plates. At the same time, such peripheral distribution screens can be connected to the inner surface of the gas duct by jumpers. And in the above-mentioned heat transfer zone, the gas duct can have a round or rectangular cross-section. In addition, the above-mentioned at least one pipe of additional heat exchange can be made straight or zigzag. All specified additional heat exchange pipes of the above-mentioned additional heat exchange section can be located in one plane crossing the gas duct.

In addition, in some cases, the above burner can be equipped with an automatic fuel and air supply device.

Next, the cause-and-effect relationship between the set of features of the declared decision because of the design of the boiler and the technical result is given. Given that the claimed technical solution can be modified and have alternative implementation options, the following description is given as an example to characterize its essence and possibility of implementation. It should be clear that the detailed description provided is not intended to limit the claimed solution to the given individual variants of embodiment, but on the contrary, includes all modifications, equivalents and alternatives that fall under the essence and scope of patent protection defined by the formula of the claimed boiler design solution.

The essence of the claimed technical solution is explained by the schematic drawings shown in Fig. 1 (frontal projection) and Fig. 2 (profile projection), which are made exclusively with a view to simplifying the explanation of the essence of the decision. These drawings are in no way intended to reflect the exact design of the real device and in no way limit the possibility of implementing the declared boiler design solution and possible other options for its implementation within the limits of the technical solution disclosed in the formula. The given drawings (Fig. 1, Fig. 2) explain the essence of implementing the solution using a conditional material object, which is characterized by the features included in the formula.

A boiler, in this description and the formula of the declared technical solution, means a device in which the heat released during the combustion of organic fuel is used to generate steam or heat a liquid under pressure above atmospheric, which is consumed outside the limits of this device. In such a heating device, gaseous combustion products are used as a source of thermal energy, and not only water, but also other liquid heat carriers are considered as the liquid that is heated or from which steam is obtained.

The declared solution can be applied in the above-mentioned boilers, which in their design contain a furnace with a burner, a combustion chamber of the furnace, which is connected to the gas duct, in particular, in solid fuel boilers. The specified furnace is a boiler device designed for burning, in particular, organic fuel, partial cooling of combustion products and ash removal (DSTU 2369-94). The burner is a device for introducing fuel and air necessary for its combustion into the furnace of the boiler (GOST 23172-78), which according to one of the variants can be made with a device for automatic fuel and air supply. And the furnace combustion chamber is the part of the boiler furnace in which ignition and combustion of the main mass of fuel takes place (GOST 23172-78).

In Fig. 1 and Fig. 2 schematically shows the main elements of the boiler design within,

Of those sufficient to explain the essence of the declared decision and the possibility of its implementation. At the same time, elements such as a furnace with a burner, a combustion chamber of the furnace, which together form the zone of the source of the flow of gaseous combustion products, are not shown in the drawings.

As can be seen from the drawing (Fig. 1, Fig. 2), in a specific embodiment of the claimed solution, the boiler has a casing 1, which should usually have a suitable heat-shielding layer (not shown in the drawings), which is located along the outer wall 2 of the casing 1.

Located in the housing 1, the wall Z of the gas duct 4 separates the channel for the passage of the flow 5 of gaseous combustion products and the belt channel b for the passage of liquid, thanks to which the above-described principle of construction of the heat exchange part "pipe in a pipe" is realized. The indicated gas pipe 4 and belting channel b for the passage of liquid are located coaxially and, in a specific embodiment, have similar cross-sectional outlines, which can be round or square.

As already mentioned above, the combustion chamber of the furnace (not shown in the drawings) is connected to the gas duct 4, which is a channel designed to direct the products of fuel combustion and place the heating surfaces of the boiler (DSTU 2369-94). That is, the inlet 7 of the gas duct 4 is the inlet of the stream 5 of gaseous combustion products from the zone of the source of this stream, formed by the above-mentioned, but not shown in the drawings, furnace with a burner and combustion chamber of the furnace. And at the opposite end of the gas duct 4 is the outlet 8 of the gas duct.

In the specific case of implementation of the stated solution, the belting channel 6 for the passage of liquid has, located on the side of the entrance 7 of the gas duct 4, the inlet pipe 9 of the belting channel 6.

And on the side of the outlet opening 8 of the gas duct 4, the outlet pipe 10 of the belting channel 6 is located (Fig. 1).

At the same time, according to the proposed solution, the above heat transfer zone of the gas duct 4 has at least one section 11 of the main heat exchange and at least one section 12 of additional heat exchange. The specified section 11 of the main heat exchange is formed by at least two successively installed screens 13 of the peripheral distribution of the flow 5 of gaseous combustion products. And the specified area 12 of additional heat exchange is formed by one screen 13 of peripheral flow distribution and one screen 14 of central flow distribution 5 of gaseous combustion products or one screen 13 of peripheral flow distribution and the outlet 8 of gas duct 4.

The above-mentioned section 12 of additional heat exchange contains at least one pipe 15 of additional heat exchange, crossing the gas duct 4 and the inner space of which is connected to the inner space of the above-mentioned belting channel b for the passage of liquid. Pipes 15 of additional heat exchange can be made straight or zigzag. All such pipes 15 of the above section 12 of additional heat exchange can be located in one plane crossing the gas duct.

In the specific case of implementing the claimed technical solution, as shown in the drawings (Fig. 1, Fig. 2), the gas duct 4 is located vertically, however, the considered solution can be implemented with a horizontal placement of the gas duct 4. In addition, to ensure free flow liquid through pipes 15 of additional heat exchange, in a specific embodiment of the claimed solution, all pipes 15 can be located with a slight deviation from the horizontal.

The indicated screens 13 of the peripheral flow distribution are coaxial with the gas duct 4 and have the form of transverse partitions, which are made in such a way that they have an outline similar to the outline of the cross section of the gas duct 4. As a result of the location of the screens 13 of the peripheral flow distribution, slit-like openings 16 are formed along the inner surface of the gas duct 4 Screens 13 of the peripheral flow distribution can be made in the form of plates and installed due to several bridges (not shown in the drawings) that cross the slit-like openings 16 and connect these screens to the wall 3.

The specified screen 14 of the central distribution of the flow 5 of gaseous combustion products is coaxial with the gas duct 4 and has the form of a transverse partition, which on the periphery has a continuous connection with the inner surface of the gas duct 4, i.e. wall 3, and in the central part contains an opening 17 for the passage of gaseous combustion products.

Considering the fact that the heat exchange part of the boiler, which is located between the source of the flow of gaseous combustion products and the smoke removal channel, should not create obstacles to the flow of gaseous combustion products, the cross-sectional area of the heat transfer zone should be at least the area of the exit opening from this zone. Therefore, all the above-described pipes 15 of additional heat exchange, screens 13 of peripheral flow distribution and screens 14 of central flow distribution are made and placed in such a way that the channel formed in gas duct 4 for

From the flow passage 5 of gaseous combustion products has a cross-sectional area not less than the area of the outlet opening 8 of the gas duct 4. At the same time, the outlet opening 8 of the gas duct is located after the last one in the direction of the flow 5 of the combustion products of the peripheral flow distribution screen 13 or the last of the above-mentioned at least one additional heat exchange pipe 15 . That is, all the holes formed by the screens 13 of the peripheral flow distribution, namely the slit-like holes 16, taking into account their reduction by the above-mentioned jumpers for holding the screens 13, and the holes 17 of the screens 14 of the central flow distribution have an area not less than the area of the outlet opening 8 of the gas pipe 4. At the same time , the pipes 15 of the additional heat exchange, the screens 13 of the peripheral flow distribution and the screens 14 of the central flow distribution are placed relative to each other at a distance that ensures the cross-sectional area of the flow 5 that changes in direction and shape, which is not less than the area of the outlet opening 8 of the gas duct 4.

In a specific embodiment of the claimed technical solution, as shown in the drawings (Fig. 1, Fig. 2), all the above-described elements, which are located in the heat transfer zone of the gas duct 4, are made and placed in the following manner in the direction of the flow 5 of combustion products.

First, there is the first above-described screen 13 of peripheral flow distribution, after which there is the first layer of pipes 15 of additional heat exchange, which is formed by four equidistant straight round pipes 15 placed in one plane. After the first layer of pipes 15, the first screen 14 of central flow distribution is placed. In this way, the first above-mentioned section 12 of additional heat exchange is formed. Further, in the direction of the flow 5 of combustion products, the second and third screens 13 of the peripheral distribution of the flow 5 of gaseous combustion products are sequentially installed, which form the first section 11 of the main heat exchange of the gas duct 4. After the third screen 13 of the peripheral flow distribution, a second layer of pipes 15 is placed, which has such the same performance as the first. After this layer of pipes 15, the second screen 14 of the central flow distribution is placed. At the same time, indicated by the third screen 13, the second tier of pipes 15 and the second screen 14, the second section 12 of additional heat exchange is formed. Immediately after the second screen 14 of the central flow distribution, the fourth and fifth screens 13 of the peripheral flow distribution 5 are sequentially installed, which form the second section 11 of the main heat exchange of the gas duct 4. Next is the third tier of pipes 15, which has the same design as the first. At the same time, the fifth screen 13, the third tier of pipes 15 and the outlet 8 of the gas duct 4 form the third section 12 of additional heat exchange.

In addition, according to the proposed design solution of the boiler, according to one of the implementation options, the above-mentioned burner can be made with a device for automatic fuel and air supply (not shown in the drawing).

The boiler described above, in which the claimed technical solution is implemented, works as follows.

During the combustion of the above-mentioned fuel, a flow 5 of gaseous combustion products is formed, which, due to the thrust arising as a result of the difference in temperature and pressure, enters the inlet 7 of the gas duct 4.

The specified flow 5 collides with the first screen 13 of the peripheral distribution of the flow.

As a result of the specified thrust, the stream 5 of gaseous combustion products is forced to bypass the first screen 13, passes through the slit-like opening 16 and changes the shape of its cross-section. As a result of such a redistribution of the flow 5 of gaseous combustion products, it is pressed against the wall 3. Then, due to the draft, the flow 5 narrows to the size of the opening 17 of the first screen 14 of the central flow distribution. At the same time, flow 5 passes through the first tier of pipes 15 of additional heat exchange, where through the walls of the pipes 15 heat exchange between heat carriers takes place. This is how heat exchange is carried out in the first section 12 of additional heat exchange.

After that, the narrowed flow 5 of gaseous combustion products collides with the second screen 13 of the peripheral flow distribution and, due to traction, is forced to bypass this screen, passes through the slit-like opening 16 and changes the shape of its cross-section. As a result of such a redistribution of the flow 5 of gaseous combustion products, it is pressed against the wall C and acquires a tube-like shape in the space to the second slit-like opening 16 formed between the third screen 13 of the peripheral flow distribution and the wall 3. This shape of the flow 5 is preserved between the second and third in the direction flow 5 of gaseous combustion products through the screens 13 due to the specified draft. At the same time, a thin layer of gaseous combustion products is formed, which is pressed against the wall C, through which heat exchange between heat carriers takes place. This is how heat exchange is carried out in the first section 11 of the main heat exchange.

Further, the flow 5 of gaseous combustion products, under the influence of draft, is similarly redistributed and passes through the second section 12 of additional heat exchange, through the second section 11 of the main heat exchange, through the third section 12 of additional heat exchange and enters the outlet 8 of the gas duct 4 and can be removed through the channel smoke removal

At the same time, the liquid is directed into the belting channel 6 through the inlet pipe 9, and this liquid comes out through the outlet pipe 10. The direction of the liquid can be carried out naturally, that is, by overflow due to the pressure created in the system to the outside, or with the help of a pump.

Directing the flow of 5 gaseous combustion products can be carried out naturally, due to the burning of fuel and the natural upward movement of hot gaseous combustion products of this fuel, due to the above-mentioned thrust. The intensity of flow 5 of gaseous combustion products can increase as a result of gas (air) blowing from the fuel combustion zone. The thickness, thermal conductivity and area of the wall C affect the rate of liquid heating or vaporization.

As a result of the described redistribution of the flow 5 of gaseous combustion products, the thickness of the layer of this flow decreases in the areas 11 of the main heat exchange and, accordingly, the distance between the heat-carrying particles located at the maximum distance from the wall C, through which heat is transferred to the liquid, decreases. Thus, the efficiency of heat transfer increases, which reduces heat loss along with particles of gaseous combustion products emitted through the smoke removal system. And as a result of the redistribution and narrowing of the flow 5 of gaseous combustion products in the sections 12 of the additional heat exchange, the coverage of the surface of the pipes 15 of the additional heat exchange increases, due to which the heat transfer efficiency also increases. At the same time, the very presence of pipes 15 increases the total heat exchange area.

As can be seen, regardless of the size of the peripheral flow distribution screens 13 and, accordingly, the area of the slit-like openings 16 formed, the efficiency of heat transfer from gaseous combustion products through wall C to the liquid increases. Likewise, regardless of the size of the holes 17 of the screens 14 of the central flow distribution, the efficiency of heat transfer through the walls of the pipes 15 increases. At the same time, it is not required to change the cross-section of the heat exchange wall of the gas duct, the overall dimensions of the heat exchange part of the gas duct, the temperature and volume of gaseous products obtained during fuel combustion and the mode of supply of the heated liquid.

For those skilled in the art, possible further modifications of the claimed subject matter encompassed by the nature and scope of the claimed subject matter as disclosed in the formula are apparent.

The proposed solution makes it possible to create a design of a boiler for obtaining steam or heating a liquid, in which heat is transferred from gaseous combustion products to the liquid through the wall, with a higher efficiency of heat transfer without changing the cross-section of the heat exchange wall of the gas duct and its overall dimensions, temperature and volume gaseous products obtained during fuel combustion and the heating liquid supply mode.

Claims (2)

USEFUL MODEL FORMULA 1. A boiler containing a furnace with a burner, a combustion chamber of the furnace, which is connected to the flue, and part of the flue wall has a zone of heat transfer from gaseous combustion products to the liquid, where these gaseous combustion products are in contact with the inner surface of the flue wall, and with the outer surface the walls of the gas duct are in contact with the liquid, i.e., the specified part of the wall of the gas duct, which forms the heat transfer zone, separates the channel for the passage of the flow of gaseous combustion products and the belting channel coaxial with it for the passage of the heating liquid, which is characterized by the fact that the above-mentioned heat transfer zone of the gas duct has at least one section of the main heat exchange and at least one section of additional heat exchange, and the specified section of the main heat exchange is formed by at least two consecutively installed screens for the peripheral distribution of the flow of gaseous combustion products, and the specified section of the additional heat exchange is formed by one screen for the peripheral distribution of the flow and one screen of the central distribution of the flow of gaseous combustion products or by one peripheral flow distribution screen and the exit opening of the gas duct, in addition, such an additional heat exchange section contains at least one additional heat exchange pipe crossing the gas duct, the internal space of which is connected to the internal space of the above-mentioned belting channel for fluid passage, in addition, the specified screens of peripheral flow distribution are coaxial with the gas duct and have the form of transverse partitions, which are made in such a way that they have an outline similar to the outline of the cross section of the gas duct, and form slit-like openings along the inner surface of the gas duct, and the specified central flow distribution screen of gaseous combustion products is coaxial with the flue and has the form of a transverse partition, which on the periphery has a continuous connection with the inner surface of the flue and contains in the central part an opening for the passage of gaseous combustion products, while all the above-described pipes of heat exchange, peripheral flow distribution screens and central flow distribution screens are made and placed in such a way that the channel formed in the gas duct for the flow of gaseous combustion products has a cross-sectional area not less than the area of the exit opening of the gas duct located after the last one in the direction of the flow of combustion products of the peripheral screen flow distribution or the last above-mentioned at least one pipe of additional heat exchange. 2. Boiler according to claim 1, which is characterized by the fact that the above-mentioned peripheral flow distribution screens and central flow distribution screens are made in the form of plates, and such peripheral distribution screens are connected to the inner surface of the gas duct by jumpers, and in the above-mentioned heat transfer zone, the gas duct has a round or rectangular cross-section, in addition, the above-mentioned at least one additional heat exchange pipe is made straight or zigzag, and all the indicated additional heat exchange pipes of the above-mentioned additional heat exchange section are located in the same plane crossing the gas duct. Z. Boiler according to claim 1, which differs in that the above burner is made with a device for automatic fuel and air supply.