RU2206029C1 - Heating appliance - Google Patents

Abstract

FIELD: thermal power plants; air heating plants for air heating of stock-rearing farms. SUBSTANCE: proposed heating appliance has cylindrical housing with axial-flow fan at end face; said fan is provided with impeller and electric motor; it is mounted in housing at spaced relation; proposed heating appliance includes also cylindrical furnace divided into two chambers by means of diaphragm; end face of this furnace is provided with swirler made in form of disk with cuts and inclined blades; heating appliance is also provided with burner located inside first (in way of motion of air) chamber and connected with fuel source by means of pipe line; second chamber is provided with slots with guide baffles projecting to zone of clearance of fan; swirler is provided with additional flat disk tightly adjoining swirler and mounted coaxially for making turn; said flat disk has cuts whose number is equal to number of cuts in swirler; cuts in disk and in swirler have similar shape. EFFECT: improved quality of mixture being burnt; reduced noise level. 6 cl, 1 dwg

Description

 The invention relates to thermal power plants and, in particular, to installations for heating air, intended for use in air heating systems of livestock buildings.

A heating device for livestock buildings is known, comprising a cylindrical body with an axial type fan mounted on the end face with an impeller and an engine, a coaxial body and a cylindrical furnace and burner inserted into it, connected by a pipeline to a fuel source, the furnace on the fan side being equipped with a confuser and installed with the possibility axial movement, and the burner is made in the form of a hollow perforated cone-shaped housing arranged in the direction of gas movement behind the fan th fairing with a smaller taper angle than that of the converging tube (RU patent 2126943 C1, IPC ⁶ F 26 B 23/02, Bul. 6, 02.27.1999). Featuring the possibility of high-quality mixing of fuel and primary air, as well as smooth regulation of heat output, the described heating device is quite complicated to manufacture and has a reduced intensity.

 Closest to the proposed invention is a heating device for livestock buildings, comprising a housing with an axial type fan mounted on the end face with an impeller and an electric motor, a coaxial housing and a cylindrical furnace and burner inserted into it by a diaphragm into two chambers and connected to a fuel source by a pipeline (gaseous or liquid). The fuel is mixed with the air necessary for combustion by a swirler located at the end of the furnace, made in the form of a disk with cutouts and inclined blades ("Instructions for use with installation instructions for Jet Master GP 75", code 99 97 0933, Edition 11.96, M 933 RU , BIG DUTCHMAN INTERNATIONAL GmbH). The disadvantage of this heating device is the insufficiently complete mixture of fuel and air and the practical impossibility of regulating the coefficient of excess air. Since the formation of the swirl in this case does not lend itself to theoretical justification and calculation, its experimental selection can be acceptable only for a single design with constant fan performance. At the same time, it becomes impossible to smoothly change the productivity of the heating device by heat, and poor-quality mixing of air and fuel leads to an excess of carbon monoxide in the exhaust gases, which is unacceptable when used directly to heat the room. The heater of the described design also has a reduced intensity, and therefore, increased dimensions at a certain power.

 The problem solved by the invention is to create a heating device of the specified type with high intensity.

 The technical result achieved is to improve the quality of the combustible mixture of fuel and air, and therefore, to reduce the content of carbon monoxide in the exhaust gases. In addition, the design proposed below allows you to smoothly adjust the thermal power of the device, to reduce noise during its operation.

 To solve the problem and achieve a technical result in the heating device, which includes a cylindrical body with an axial type fan mounted on the end face with an impeller and an electric motor, a coaxial body inserted into it with a gap and a cylindrical furnace divided by a diaphragm into two chambers, the end of which is on the fan side has a swirl made in the form of a disk with cutouts and inclined blades, and connected by a pipeline inside the first chamber in the direction of air movement source fuel burner, the second chamber is provided with slots projecting into the gap area towards the fan guide visors, and a swirler provided with tight-fitting, and it is coaxially mounted rotatable flat disc with optional cut-outs the number of which is equal, and the shape is identical with cutouts swirler. Slots with visors are placed in one or more planes perpendicular to the axis of the furnace, and in the latter case in the corridor or staggered order. Slots with visors are placed at an angle to the generatrices of the cylindrical furnace. The axial fan motor is placed in the direction of air movement behind the impeller inside the heater housing. The end face of the body on the fan side is equipped with a rim made of a pipe of round or oval profile and rigidly connected with the body. The electric motor is mounted with the ability to control the speed.

 The invention consists in the following. The installation of a cylindrical furnace inside the apparatus coaxially allows it, both in the case of the closest technical solution and in the proposed apparatus, to separate the air supplied by the fan directly after the impeller into two flows, one of which enters the burner zone for mixing with fuel (primary air). This flow, passing through the cutouts of the swirler, is then twisted by inclined blades, which provides a mixture of air and fuel. If in the case of the prototype the size of the cutouts of the swirler cannot be changed, if necessary, to increase or decrease the thermal power of the apparatus, then in the case of the invention, the size of the cutouts of the swirl for air passage can be easily adjusted by turning an additional flat plane adjacent to the swirl drive. The specified disk also provides cutouts, the number of which coincides with the number of cutouts of the swirl when they are the same shape.

 The cylindrical furnace in the prototype and in the present invention is divided by a diaphragm into two chambers. In the first chamber in the direction of air movement in both cases, a burner is connected by a pipeline to a fuel source. A significant difference between the devices is that the design of the heating device according to the prototype allows additional mixing of air and fuel in the second chamber due to the diaphragm separating chamber, but only of the air that enters the furnace through the swirl cutouts into the first chamber. Thus, in the known construction, when the second chamber performs the function of afterburning the fuel mixture, no additional air can be introduced into the latter when this is naturally necessary. The effect of mixing the flow using the diaphragm separating the chambers of the furnace is also insufficient for high-quality mixing of the components and burning of the mixture. In the present invention, the second chamber is provided with slots with projecting visors protruding into the gap between the device body and the furnace towards the fan. Slots can be placed in one or more planes perpendicular to the axis of the furnace, and in the latter case, in a corridor or staggered manner. Slots with visors can also be installed at an angle to the generatrices of the cylindrical furnace. Thus, in the present invention, a certain desired part can be selected and sent to the second chamber from the air stream flowing around the furnace (moving in the gap between the device body and the furnace) and providing cooling of the case. The amount of air drawn is determined by the size and number of slots, as well as the design of the visors. In this case, additional air enters the second chamber, which ensures complete combustion of the fuel mixture. Jet injection of additional air and swirling the total flow in the second chamber contribute to the improvement of mixing of additional air with an already burning mixture of air and fuel.

 In all known heating devices of the indicated type, the fan is installed in such a way that an impeller is placed inside the device’s housing at its end, and the electric motor is outside the housing. Such placement seems natural and is generally accepted. However, this arrangement of the fan has a significant drawback, namely that the rarefaction that occurs in the zone of the impeller axis promotes the suction of air, already directed by the fan into the casing of the apparatus, by the impeller. This reduces the actual heat output of the heating device, since the amount of flue gas generated in the heater is less than that which could be obtained taking into account the total performance of the axial fan, which can be achieved in this case by installing a cowl. When placing the engine inside the housing behind the impeller (in the direction of air flow), the role of the fairing is played by the engine itself, which allows to increase the heating capacity of the heating device without introducing additional elements into the design.

 The operation of known heating devices of this type is accompanied by increased noise. It was experimentally found to significantly decrease when equipping the end of the device casing from the fan side with a rim made of a pipe of round or oval profile and rigidly connected to the casing.

 The obvious possibility of smoothly regulating the heating capacity of the heating device arises with a smooth change in the fan speed, which complicates the design, but in some cases it may be justified.

 A comparative analysis of the prototype and the proposed technical solution shows the presence in the last row of distinctive features, which allows us to confirm its compliance with the patentability criterion of "novelty."

 The absence of such solutions (in combination) in the field of designing heating devices and in related fields determines the compliance of the proposed invention with the patentability criterion of "inventive step", since it does not follow explicitly from the current level of technology and is not obvious to specialists.

 In the present invention is missing anything that makes the implementation of the solution impossible or difficult. At the same time, the livestock sector of agriculture is constantly increasing the need for heating devices of this type because of their simplicity, reliability and ease of use. The latter allows us to confirm the compliance of this decision with the patentability criterion of "industrial applicability".

 The present invention is illustrated in the drawing.

 The heating device includes a housing 1 with an axial fan 2 with an impeller 3 and an electric motor 4 located at its end, and the motor 4 is installed behind the impeller 3 in the air flow. And the motor 4 and the impeller 3 are placed inside the housing 1. Inside the housing 1, it is aligned with it a cylindrical furnace 5 is installed, divided by a diaphragm 6 into two chambers 7 and 8. The end face of the furnace 5 from the side of the fan 2 is equipped with a swirler 9 made in the form of a disk with cutouts 10 and inclined blades 11. It fits snugly against the flat end of the swirl 9 axial to it and mounted with the possibility of rotation, an additional flat disk 12 with cutouts 13, the number of which is equal, and the shape is the same with the cutouts of the swirl 9. In the first chamber 7 of the furnace 5 along the air there is a burner connected by a pipe 14 to a fuel source (for example, natural gas) 15. The second chamber 8 of the furnace 5 is provided with slots 16 with protruding guide visors 18 protruding into the gap zone 17 between the furnace 5 and the housing 1 and directed towards the fan 2. The slots 16 in the described embodiment are placed at an angle to the generatrices th combustor in a single plane perpendicular to the tool axis (invention also contemplated the placement of slits 16 in several planes perpendicular to the axis of the heater, in which case in inline or staggered). The end face of the housing 1 on the side of the fan 2 is equipped with a rim 19 rigidly connected with the housing 1, made of a pipe of round or oval profile. The engine 4 can be installed with the possibility of changing the speed.

 The heater of the present invention operates as follows.

 Natural gas through a pipe 14 enters the burner 15. Installed inside the housing 1, the fan 2 directs air into the furnace 5 and into the gap 17 between the furnace 5 and the housing of the heating device 1.

 Air enters the firebox 5 through a swirl unit made in the form of a disk with cutouts 10 and inclined vanes 11 installed at the end face of the firebox 5 from the fan side 9. The amount of air entering the firebox 5 can be changed when the heating device is set to a certain heat output due to the rotation of the tight-fitting to the swirler 9 of an additional flat disk 12 with cutouts 13. A change in the air supply allows you to get in the first chamber 7 the primary gas-air mixture of the desired composition. Naturally, the first chamber 7 is provided with a device for igniting the mixture and, if necessary, for maintaining the combustion of the primary mixture. When advancing the mixture along the furnace 5, its subsequent mixing is ensured by the diaphragm 6. However, the average composition of the already formed mixture does not change.

 In existing structures, at the exit from the furnace 5, very poor mixing of the air coming from the gap 17 between the furnace 5 and the housing 1, and the burning mixture occurs. Abrupt cooling of the final mixture does not allow to achieve high-quality combustion while increasing the load of the device. In the proposed solution, the situation has been significantly changed. Due to equipping the second chamber 8 of the furnace 5 with slots 16 with visors 18 protruding into the gap zone 17 towards the fan 2, additional air enters the second chamber 8 from the part of the air flow moving in the gap 17. Installing the slots 16 at an angle to the generatrices of the cylindrical furnace 5 spins the flow in the second chamber 8.

 Improving mixing and preventing sudden cooling of the mixture in the second chamber 8 allows for high-quality combustion of fuel and with an increase in the heat load of the device. Giving the housing 1 of the heating device stiffness by installing the rim 19 significantly reduces the noise during operation of the device, which was established during the experimental verification of the solution. An additional possibility of regulating the thermal power of the heating device is provided by changing the speed of the engine 4 of the axial fan 2. When installing the axial fan 2 inside the housing 1 in such a way that the motor 4 is located behind the impeller 3, the value of the useful air flow increases. The consequence of this is an increase in the thermal power of the heating device. In this case, the engine 4 carries the fairing function and prevents partial return of air to the fan from the total air flow formed by the impeller 3.

With a case diameter of 0.47 m and a length of 1.5 m in a heating device of a known type, the total thermal power is not more than 90 kW. With a case diameter of 0.39 m and a length of 1.15 m, a heating power of> 100 kW was achieved in the heater of the present invention. Thus, during the experimental verification of the proposed technical solution, an increase in the specific productivity (kW / m ³ ) of the heating device was more than 2 times higher than that of the known type of heating device.

Claims (6)

 1. A heating device, comprising a cylindrical body with an axial type fan placed on the end face with an impeller and an electric motor, a coaxial body inserted into it with a gap and divided by a diaphragm into two chambers, a cylindrical furnace, the end of which on the fan side has a disk made with cutouts and swirl blades, and a burner located inside the first chamber in the direction of air movement, connected by a pipeline to the fuel source, characterized in that the second chamber is provided with on slots with guiding visors protruding into the gap towards the fan, and the swirl is equipped with a tight-fitting and installed coaxially with it with the possibility of rotation of an additional flat disk with cuts, the number of which is equal, and the shape is the same with the swirl cutouts.  2. The heating device according to claim 1, characterized in that the slots with visors are placed in one or more planes perpendicular to the axis of the furnace, and in the latter case in a corridor or staggered manner.  3. The heating device according to claims 1 and 2, characterized in that the slots with peaks are placed at an angle to the generatrices of the cylindrical furnace.  4. The heating device according to paragraphs. 1-3, characterized in that the axial fan motor is placed in the direction of air movement behind the impeller inside the housing of the heating device.  5. The heating device according to claims 1 to 4, characterized in that the end face of the housing on the fan side is provided with a rim made of a pipe of round or oval profile and rigidly connected to the housing.  6. The heating device according to claims 1 to 5, characterized in that the electric motor is installed with the ability to control the speed.