阅读说明：本技术 模块化热能综合体和用它实现矿井空气加热的方法 (Modularized heat energy complex and method for heating mine air by using same ) 是由 卡拉谢娃·塔玛拉·米哈伊洛芙娜 于 2020-06-16 设计创作，主要内容包括：本发明涉及模块化热能综合体,包括,至少一个上层模块,至少一个下层模块和至少一个工艺模块,每一个模块都包含支撑框架和至少一个墙面板,所有的模块都可以连接在一起。每个上层模块包含燃料供应系统和冷气管道,每个下层模块包含热力组件和热交换器。另一方面,热力组件包括具有燃料仓的燃烧室,与之相连的鼓风系统,二次鼓风系统和回收系统。此外,穿过上层模块和下层模块的清洁系统和排烟系统连接到燃烧室。热交换器与通过下层模块的热气管道和通过上层的冷气管道连接。热能综合体通过工艺模块中的自动控制系统进行控制。本发明是紧凑的,安装简单和便于使用。烟道气体多层次的净化减少了对使用者健康的危害。燃烧室使用固体燃料。(The present invention relates to a modular thermal energy complex comprising at least one upper module, at least one lower module and at least one process module, each module comprising a support frame and at least one wall panel, all modules being connectable together. Each upper module contains a fuel supply system and a cold air duct, and each lower module contains a thermal assembly and a heat exchanger. In another aspect, the thermal assembly includes a combustion chamber having a fuel reservoir, an air blast system associated therewith, a secondary air blast system, and a recovery system. Furthermore, a cleaning system and a fume extraction system passing through the upper and lower modules are connected to the combustion chamber. The heat exchanger is connected to a hot gas line through the lower module and a cold gas line through the upper module. The thermal energy complex is controlled by an automatic control system in the process module. The invention is compact, simple to install and convenient to use. The multi-level purification of the flue gas reduces the harm to the health of the user. The combustion chamber uses solid fuel.)

1. A modular thermal energy complex, comprising: at least one upper module, at least one lower module and a process module, each module comprising a prefabricated support frame and at least one wall panel,

each upper module contains a fuel supply system and a cold gas duct,

each lower module comprises a thermal assembly and a heat exchanger, while the thermal assembly comprises a combustion unit with a combustion chamber, to which are connected a blowing system, a secondary blowing system and a recovery system,

in addition, an ash removal system and a smoke exhaust system passing through the upper module and the lower module are connected to the combustion chamber,

the heat exchanger is connected with the hot air pipeline of the lower module and the cold air pipeline of the upper module, the heat energy complex is controlled by an automatic control system in the process module, and all the modules are connected with each other.

2. A modular thermal energy complex according to claim 1, wherein a process module is electrically connected to more than one upper and lower module.

3. A modular thermal energy complex according to claim 2, wherein at least one upper module and at least one lower module comprise respective end wall panels.

4. A modular thermal energy complex according to claim 1, comprising two upper modules and two lower modules.

5. A modular thermal energy complex according to claim 4, wherein the hot gas duct is connected to the main air duct.

6. A modular thermal energy complex according to claim 4, wherein adjacent flues from lower modules merge into a main flue.

7. A modular thermal energy complex comprising at least one upper module, at least one lower module and at least one process module,

each upper module contains a fuel supply system and a cold gas duct,

each lower module comprises a smoke exhaust system and a thermal assembly, the thermal assembly comprises a combustion unit with a combustion chamber, a furnace blast system and a secondary blast system,

a smoke exhaust system connected to the combustion chamber through each upper module and each lower module, comprising a flue, a bypass air flue, an ash remover, a smoke exhaust and a chimney,

in addition, each lower module is provided with at least one set of heat exchangers connected with a hot gas pipeline passing through each lower module and a cold gas pipeline passing through each upper module,

and an automatic control system configured in the process module,

and the convection pipe sleeve arranged on the combustion chamber,

the ash removal system is arranged in the combustion chamber.

8. A modular thermal energy complex according to claim 7, wherein the combustion chamber is provided with flue gas cleaning means.

9. A modular thermal energy complex according to claim 8, wherein the preliminary treatment stage of the flue gases is a transition from the flue in the rear wall of the combustion chamber to the cooling chamber.

10. A modular thermal energy complex according to claim 7, wherein the housing of the combustion chamber is provided with a convection current jacket.

11. A modular thermal energy complex according to claim 7, wherein at least one nozzle is provided in a side wall of the combustion chamber.

12. A modular thermal energy complex according to claim 7, wherein the secondary air blowing system is connected to a fan blower.

13. A modular thermal energy complex according to claim 7, wherein the cold air duct is configured to exchange heat with the bypass air duct.

14. A method for heating mine air, fuel is supplied to a combustion unit with a combustion chamber in a lower module by a fuel supply system of an upper module, the combustion chamber supplies air through an air blowing system and a secondary air blowing system of a lower module while the fuel is combusted,

the smoke generated in the combustion process is sent to a gas cooling chamber of the combustion chamber, then the smoke is conveyed to a heat exchanger of a lower module through a bypass air passage in an upper module, the air conveyed to the heat exchanger through a cold air pipeline is preheated by the bypass air passage and the upper module,

in the air heater of the heat exchanger assembly, the air is further heated and fed into the mine,

and then sending the cooled flue gas into a chimney, wherein the generated ash and slag can be treated by an ash removal system of the lower module, and monitoring is realized by an automatic control system in the process module.

15. The method of claim 14, wherein the flue gas is additionally fed to a combustion chamber for first stage cleaning.

16. The method of claim 14, wherein the flue gas is cleaned by inertial collection from a flue in the back wall of the combustion chamber into a gas cooling chamber.

17. The method of claim 16, wherein the ash and slag particles produced by the cleaning are returned to the combustion chamber for combustion by a recovery system.

18. The method of claim 14, wherein air is delivered to the combustion chamber by a blower through a convective liner of the combustion chamber.

19. The method of claim 14, wherein the second blast of air is fed into the combustion chamber through a nozzle.

20. The method of claim 14, wherein the flue gas is recovered by inertial collection, further cleaned by a transition flue of the heat exchanger assembly, and then cleaned by a dust collector.

21. The method of mine air heating of claim 14, wherein the ash and slag are processed by a groove ash removal system conveyor located in the bottom module.

22. A method of heating mine air as claimed in claim 14, wherein the heated air is fed into the mine through the main air duct.

23. The method of claim 14, wherein the flue gas is fed through a flue stack to a stack.

Technical Field

An important problem at present is to establish a convenient and easy-to-manage large-scale heating system for a large-scale indoor space. If it is necessary to supply heat to underground mine facilities, the process of using the heating system should eliminate the risk of additional thermal damage and health hazards to the user. In addition, the heating system should be used in consideration of convenience of system configuration so that the system can rapidly increase heating energy. This need inevitably arises as mineral space increases during mineral development and exploitation.

The present invention relates to heating systems for use in various installations, both on the ground and underground, for the purpose of generating thermal energy for heating, for example, in mine air ventilation installations.

Background

It is known that in the patent of invention RU 2189533C 2 a heating, ventilating and preheating device is disclosed (international patent classification F24D 15:00, F24H 3/02, E21F/00; published on 20/09/2002). The air inlet air heating device comprises a main air passage for heating, transporting and delivering hot air to mine ventilation, and comprises a fuel oil combustion chamber, an air heater, a fan, a flue and a pipeline. The known device has the disadvantage of a low fuel burning rate and a low heater efficiency. Furthermore, the known devices are arranged in major buildings and cannot be installed quickly.

As is well known, the method of mine air heating and ventilation is disclosed in the RU 2014121233 a patent application; (International patent Classification F24D 15/00, published in 10.12.2015.) A method for supplying heat to underground mine ventilation is to generate hot gas from a fuel oil combustion chamber, to heat the air fed to an air heater by a fan by the gas fed into the air heater, and then to supply the heated gas to ventilation equipment by a hot gas distribution device. The method is characterized in that the temperature of fuel heating air is not lower than +2 ℃ of the outlet of an air heater through a closed adjusting device, and under the condition, the pressure of the closed adjusting device, a hot air blower and a hot air distributor is higher than the pressure of the mixture of the hot air blower and the mine air.

The disadvantage of this known method is the lack of a flue gas cleaning stage, which means that if this known method is used, there is a threat of environmental pollution and thus a risk to human health, and therefore the manner of this mine air heating method does not comply with safety standards.

The mine ventilation device disclosed in the invention patent is known as a heating device (RU 2386034C 1, international patent classification E21F 3/00, E21F 1/00, F24H 3/02; published 10/04/2010). The heating method and device for mine ventilation air comprises a fuel combustion chamber, a secondary blower, a convection liner, a slit ejector, an air heater, a hot air distributor device, a hot air fan, a smoke exhauster, a flue, a ventilation pipe and a detection instrument panel.

A method for heating mine ventilation air is achieved using known mine ventilation heating apparatus.

It is known that ventilation heating of mine air is disclosed in RU 2386034C 1 (international patent classification E21F 3/00, E21F 1/00, F24H 3/02; published 10.04.10.a.. Mine ventilation air heating methods and apparatus employ known methods of heating the atmosphere for ventilation of mine air by flue gases from combustion chamber flues and entering the mine through a ventilation system. It is characterized by metering the amount of hot air supplied directly into the hot air distribution unit. The combustion chamber adopts secondary air blowing, the secondary air blowing is used for providing secondary air for heating in the convection lining cover on the side wall of the combustion chamber, cold air is used for blowing in the exhaust pipe, and the blowing angle is at least 45 degrees upwards.

The disadvantages of the known device and the method for implementing the use thereof are:

the adopted flue gas purification scheme has low conversion efficiency which is not more than 50 percent.

The convection liner made in the form of a shroud is mounted on the sidewall of the combustion chamber at a distance of 50-70 mm. The cold air provided from the atmosphere cannot be heated sufficiently, which adversely affects the intensity of the combustion process.

The consequence of these factors is that with the known devices and methods, and in particular with these devices and methods, which are primarily intended to protect the health of an individual, the respiratory system of the individual, there is a great risk of harm to the health of the individual. In addition to this, the use of the known apparatus and method causes environmental pollution due to the low ash particles and slag cleaning rate of the flue gas (not more than 50%).

Furthermore, the known device is placed in a major building, making it impossible to install and remove it quickly.

It is known that mine ventilation is known to be the closest prior art disclosed in the RU 2488696C 2 patent (international patent classification E21F 3/00, F24H 3/06; published in 2013, month 07, 27). The heat supply and heat energy complex of the quarry and the large-scale factory buildings comprises: the fuel supply system, the fuel combustion chamber type air heating device, and the heat exchanger equipped with flue gas purification and discharge flue, gas channel, ash remover, smoke exhauster and smoke channel, and filtering flue. The system also includes hot and cold gas paths, as well as an ash removal system and an automatic control system.

The known plant comprises two flue gas cleaning stages and the furnace blast system is configured to heat a portion of the air supplied to the combustion chamber using an ash remover.

A method of heating mine air using known apparatus includes supplying fuel to a combustion chamber using a fuel supply system. At the same time, air is supplied to the combustion chamber by the blower system and air is supplied to the combustion chamber, flue gas generated during combustion is fed into the cooling chamber by the axial flow blower, then the flue gas is fed into the heat exchanger assembly, the heated atmosphere is fed into the mine, the cooled flue gas is fed into the chimney, and the ash and slag produced thereby are removed by the ash removal system and detected by the automatic control system. In such a case, part of the air delivered by the blower system is heated by heat exchange with the ash remover, while the flue gas is passed through two purification stages.

The known apparatus and method have several disadvantages, including a low quality of cleaning of the ash and slag contained in the flue gases and an undesirable heat consumption of the plant equipment. In particular, the heat removed by the dust separator of the known device can only be used to heat a portion of the air fed by the blower of the combustion chamber, and the air fed by the blower system to the combustion chamber is insufficiently heated, so that the intensity of the combustion process is reduced. Furthermore, a large number of devices are known to be placed in major buildings and cannot be quickly installed and removed.

Known modular thermal energy complexes are disclosed in RU 2345291C 1 (international patent classification F24H 3/00; published on 2009, 01-27), the air heater module assembly comprising a module divided into sections by partitions. In the known modular device, in order. Meanwhile, in these sections, a blower system connected to a cold air system, a hybrid air heater equipped with a gas burner, and a balancing device installed at the outlets of the air heater, the blower and the hot air mixing section are installed. In this case, all adjacent sections are connected to each other, and the connection of the automatic control system to the fuel supply regulator and the blower shaft speed regulator is made at the division of the sections.

The working principle of the device is as follows:

atmospheric air enters the blower system of the modular unit through the cold air channel and then enters the mixed air heater. In a hybrid air heater, the combustion products heat the incoming atmospheric air by the gas entering the gas burner through the gas conduit. The air heated by the blower moves into the grille of the balancing device, where the air flow is evenly distributed. The automatic control system adjusts the fuel supply and the rotational frequency of the blower, and the air is heated to a desired temperature and then mixed in the heating chamber connected to the heater chamber.

The known device has several disadvantages. The device is designed for burning gaseous fuels and this configuration does not burn solid fuels, particularly coal. Thus, it is only possible to heat the mine air when connecting the pipe to the mine or when the mining process is accompanied by the production of natural gas. In the case of such an apparatus, in the case of burning coal, the combustion products must be taken into the heated air together with the ash and slag particles produced by the combustion of the solid fuel, which is inevitable, and this will result in a significant carbon monoxide content in the air.

Furthermore, the known device has only one assembled module, but cannot be transported in a partially assembled manner due to the large dimensions.

Disclosure of Invention

The object of the invention is to create a compact, easily installed, transportable device for efficient heating of air in a mine.

The invention and the technical result, in terms of equipment and technique, are a simple design, while increasing its efficiency, the ease with which the reportable device can be installed and used, and the risk of harm to the health of the user is reduced.

According to the invention, a modular thermal energy complex is provided. The modular thermal energy complex comprises: at least one upper module, at least one lower module and at least one process module, each module comprising a support frame and at least one wall panel, all modules being interconnected. In this case, each upper module includes a fuel supply system and a cold air channel, while each lower module includes a thermal assembly and a heat exchanger. Meanwhile, the thermal assembly includes a combustion unit having a combustion chamber, including an air blowing system, a secondary air blowing system, and a recovery system. In addition, a smoke exhaust system and an ash removal system passing through the upper and lower modules are connected to the combustion chamber, and a heat exchanger is connected to a hot gas duct of the lower module and a cold gas duct passing through the upper module. The individual devices of the thermal energy complex are controlled by an automatic control system located in the process module, a significant feature of said modular thermal energy complex structure being its convenience and simplicity. Since at least one upper module, at least one lower module and the process module form an inner space, on the one hand, the number of modules can be increased if necessary. Thus increasing the number of thermal assemblies, resulting in an increase in the power of the modular thermal power complex. That is, this increases the efficiency of the modular thermal energy complex of the present invention. In addition, the present invention can be conveniently installed. On the other hand, there is a single space allowing free movement between the modules and unhindered maintenance of the individual devices, in particular the thermal components, of the modular thermal power complex within the modules, thereby facilitating the use of the invention and reducing the risk of health hazards to the user.

In this case, at least one upper module and at least one lower module and at least one wall panel. This enables heat to be retained within the module, thereby increasing the efficiency of the thermal energy complex.

In order to increase the thermal power and thus the efficiency of the modular thermal complex according to the invention, the modular thermal complex may comprise two upper modules and two lower modules. At the same time, the frames of the modules are connected by connecting adjacent modules horizontal and vertical means. A possibility for increasing the power is a thermal assembly provided in each of the lower modules. Thus, air heated by the heat generated inside the heat exchanger is also delivered into the main line duct by the hot gas, the hot air entering the mixing zone of the added air. While flue gas is removed from the plurality of heat exchangers through the main flue. At the same time, the number of upper and lower modules can be increased if the power of the modular thermal energy complex needs to be increased. A process module can serve an unlimited number of lower and upper modules because there is an automatic control system within the process module and the process module itself is electrically connected to both the upper and lower modules.

In a preferred embodiment of the invention, the following modular thermal energy complex is proposed, which comprises: at least one upper module, at least one lower module, and at least one process module. Each upper module has a fuel delivery system and a cold gas channel. Each lower module has an ash removal system and a thermal assembly comprising a combustion unit with a combustion chamber provided with a blowing system and a secondary blowing system. The combustion chamber is provided with a flue gas purification and smoke exhaust system, and comprises a flue, a bypass air flue, an ash remover, a smoke exhauster and a chimney through each upper module and each lower module. The thermal energy complex comprises at least one heat exchanger located in the lower module. Each heat exchanger is connected to a hot gas line through each lower module and a cold gas line through each upper module. And the automatic control system is located in the process module. Furthermore, the combustion unit is equipped with a convection liner and the combustion chamber is equipped with an ash removal system.

In one aspect, the purpose of such modular thermal complexes in the present modular thermal complex design is to ensure high efficiency of the thermal complex. On the other hand, this ensures that the invention is easy to install, simplifies its construction and divides the system into connectable modules.

In order to effectively remove soot particles and coal slag, the combustion chamber is equipped with a flue gas cleaning system, which means a transition from the rear wall of the combustion chamber to the cooling chamber. Such decontamination may reduce the emission of impurities into the atmosphere, thereby reducing the risk of harm to the health of the user. Furthermore, since the ash and slag particles are recycled back to the combustion chamber for further combustion, this can increase the efficiency of the application by increasing the heat generated by the modular thermal energy complex.

In addition, the combustion unit may be fitted with a convection liner to preheat the atmospheric air being fed into the combustion chamber by the blower system to ensure efficient use of the invention.

In this case, the side wall of the combustion chamber is provided with at least one nozzle for the air flowing from the secondary air blowing system to the combustion chamber. Not only the fuel combustion efficiency of the combustion chamber is ensured, but also the use efficiency of the invention is improved.

In addition, in the practice of the present invention, a secondary air blowing system may be connected to the blower, provided that the system must meet international standards, ensuring a simplified design of the present invention for ease of installation while maintaining the efficiency of the modular thermal energy complex.

Further, the cold air duct may exchange heat with the bypass air passage. Atmospheric air entering at least one of the sets of heat exchangers may be heated. This heating effectively preheats the heated air and thereby increases the efficiency of the modular thermal energy complex.

The invention also provides a method for heating the air in the mine. The method for heating the mine air is that fuel is supplied to a fuel chamber through a fuel conveying system of an upper-layer module, the fuel is combusted, and meanwhile air is conveyed to the combustion chamber through an air blowing system and a secondary air blowing system of a lower-layer module. The flue gas produced during combustion is sent to the cooling chamber of the combustion chamber and then is directed to the air duct in the upper module into the heat exchanger in the lower module. In addition, air is sent into the heat exchanger through the cold air channel of the upper module and heated by the heat exchanger air heater. The heat exchanger assembly further heats the air and feeds it to the mine, the flue gas is cooled and then fed to a chimney, and the ash and slag produced is processed by an ash removal system in the underlying module and monitored by automatic control in the process module.

The mine air heating method of the invention enables efficient combustion of the fuel. At the same time, the method can be implemented to reduce the health hazards to the user by multi-stage treatment of ash and slag in the flue gas. This is due to the fact that the flue gases of the pre-cleaning stage are further conveyed to the combustion chamber, while at the same time the flue gases are cleaned by inertia by transferring them from the rear wall of the combustion chamber to the gas cooling chamber.

In addition, the ash and slag are sent to the recovery system to the combustion chamber by cleaning, thereby increasing the heat. This ensures an increase in the amount of heat generated at the thermal energy complex assembly and thus ensures the efficiency of use of the modular thermal energy complex of the present invention. This also reduces the amount of cinder particles emitted to the atmosphere, thereby reducing the risk of harm to the health of the user.

Furthermore, the air of the combustion chamber can be conveyed to the combustion chamber through the convection liner of the combustion chamber, which enables the air to be preheated before entering the combustion chamber through the blower system. The efficiency of the fuel in the combustion chamber is ensured, and the overall utilization rate of the heat energy complex is also ensured. In this case, the secondary air blast may provide air to the combustion chamber through the nozzle, ensuring the efficiency of combustion of the fuel in the combustion chamber, thereby improving the efficiency of the overall thermal energy complex.

The flue gas can be further purified by the recovered heat exchanger assembly through inertial capture and through a filter stack. This, together with the initial cleaning, reduces the amount of ash particles discharged into the atmosphere, thereby reducing the risk of harm to the health of the user.

The ash and slag handling is carried out by means of a conveyor belt of an ash removal system which is located in a groove in the bottom of the module. This ensures the efficiency of the claimed invention in general use, particularly in heating mine air.

At the same time, hot air is conveyed to the mine through the main air duct, and flue gas is conveyed to the chimney through the main flue. This enables efficient supply of hot air to the mine during use and removal of flue gases in the case of multiple upper and lower modules.

Drawings

FIG. 1 is a schematic view of a modular thermal energy complex.

Fig. 2 is a cross-sectional view of a possible embodiment of at least one upper module 1 and at least one lower module 2 and a base 6 with a recess 7.

Fig. 3 is a side schematic view of the thermal module 9.

Fig. 4 shows a side view of the heat module 9A-a in fig. 1.

Fig. 5 shows the relative arrangement of the duct 43, the cold air delivery duct 42 and the bypass air duct 27 shown in dashed lines.

Fig. 6 shows a side sectional view of the housing 16 of the combustion chamber assembly 11 according to a possible embodiment.

Features of the present invention will be described in the following description taken in conjunction with the accompanying drawings. Within the framework of the invention, further alternatives for implementing the invention and also known technical contents may not be described in detail in order not to make the detailed description of the invention superfluous.

Detailed Description

The apparatus according to the invention is described in detail as follows:

the modular thermal energy complex of the present invention comprises at least one upper module 1, at least one lower module 2 and at least one process module 3 (fig. 2). These modules have a height of 3-3.5 meters, provide ease of transport, including remote transport, and are easier to install and remove. This is particularly important because of the need to install and remove the modular thermal energy complex at low temperatures, for example in the north of the extremes. Thus, this separate modularity provides for ease of installation and use, as well as ease of disassembly, referred to as a modular thermal energy complex.

Each module has its own self-assembled structure comprising a prefabricated support frame 4 and at least one wall panel 5. Any known steel skeleton of assembled metal structure may be used as the prefabricated support frame 4. For example, the metal structural support frame 4 may be implemented in the following manner.

Each prefabricated support frame 4 comprises: at least 8 horizontal direction devices 53, at least 4 vertical direction devices 54, and diagonal connections 55. As shown in fig. 2, the horizontal direction means 53, the vertical direction means 54 and the diagonal line connections 55 of the support frame 4 may be interconnected in any known manner in each of the lower module 2, the upper module 1 and the process module 3 assembled. Such attachment means may be welding, bolting or other known means. The horizontal direction means 53, the vertical direction means 54 and the diagonal connection 55 of each support frame 4 can in turn be realized in any known manner, such as metal beams, metal angles, etc.

Thus, the prefabricated support frames 4 of the at least one lower module 2 connecting the prefabricated support frames 4 of the at least one upper module 1 and the prefabricated support frames 4 of the process modules 3 results in an integral design of a common frame. Thus, each support frame 4 is interconnected, which is an inherent performance and complete module. The design of each module is simple and ensures that the installation and removal of each module is easy.

Since there is no separation between the prefabricated support frames 4 of each module, a space is formed inside when the modules are combined into a single structure. This ensures free movement between the modules and that all components of the modular thermal energy complex according to the invention, for example the thermal module 9, are necessary for maintenance and repair, in such a way that a combined structure with a single space can be achieved.

The wall panels 5 of each module may be made in any known manner, for example, of concrete, brick or of any known composite material used in construction. The wall panel 5 may be a sandwich panel, among others. At the same time, at least one lower module 2 can be provided with at least one wall panel 5 from the front, and at least one upper module 1 can be provided with at least one wall panel 5 from the front and the top.

However, if desired, partitions may be provided between the modules, in which case the partitions between the modules may be standard wall panels 5.

At least one lower module 2 and at least one process module 3 are mounted on a base 6. For example, the base 6 may be a concrete platform comprising a recess 7 for receiving a de-slagging conveyor belt 8 for a modular thermal complex de-ashing system. Thus, the modular thermal energy complex of the present invention can be conveniently installed.

Also, as shown in fig. 1, at least one upper module 1 is positioned above at least one lower module 2, and process modules 3 are positioned at the sides of at least one lower module 2. This is achieved by connecting the vertical direction means 54 of the support frame 4 of the process module 3 with the vertical direction means 54 of the support frame 4 of at least one lower module 2.

As a possible embodiment for implementing the above invention, the modules may be combined to obtain a single free space, as follows. In the present embodiment, at least two lower modules 2 and at least two upper modules 1 are used. Each lower module 2 has at least two shingles 5 on opposite sides of the lower module 2. In this case, each of the horizontal direction means 53, the vertical direction means 54 and the diagonal line connections 55 of the assembled support frame 4 of the lower module 2 are positioned and interconnected so as to form a uniform space between the lower modules 2, as shown in fig. 2. The edge of each lower module 2 is provided with an additional shingle 5 to function as a uniform spatial sidewall structure.

The upper module 1 is located above the lower module 2. At the same time, the horizontal direction means 53 of the support frame 4 of each upper module 1 are connected with the horizontal direction means 53 of the support frame 4 of each lower module 2, as shown in fig. 2. At least two wall panels 5 are located on opposite sides of the upper module 1 per upper module 1. Thus, the horizontal direction means 53, the vertical direction means 54 and the diagonal line connection 55 of the support frame 4 of the upper module 1 are positioned and connected to each other, and a uniform space is formed in the upper module 1. Each upper module 1 is provided with additional wall panels 5 as side walls of the composite structure, and in addition, each upper module 1 is provided with horizontal wall panels 5 on its top surface.

In addition, a possible embodiment of the invention is realized by combining modules with structurally uniform free space. In this case, there are at least three lower modules 2 and at least three upper modules 1. Each lower module 2 has at least two wall panels 5 located on opposite sides of the lower module 2. In this case, the horizontal direction means 53, the vertical direction means 54 and the diagonal line connection 55 of the support frame 4 of the lower module 2 are positioned and connected to each other so as to form a space between the lower modules 2. Each lower module 2 forms a uniform space. In addition, an additional wall panel 5 is provided as a side wall of the unified spatial composite structure.

The upper module 1 is located above the lower module 2. In this case, the horizontal direction means 53 of the support frame 4 of each upper module 1 are connected to the horizontal direction means 53 of the support frame 4 of each lower module 2. Each upper module 1 has at least two wall panels 5 located on opposite sides of the upper module 1. At the same time, the supporting frames 4 of each upper module 1 are positioned and connected to each other so that the upper module 1 forms a free space. Each upper module 1 at the free space edge is also provided with an additional wall panel 5, functioning as a side wall of the free space composite structure. In addition, a horizontal wall panel 5 is provided on the top of each upper module 1.

Each lower module 2 is arranged to accommodate a thermal assembly 9 comprising a combustion unit 11, at least one set of heat exchangers 12, a blowing system 13, a secondary blowing system 14, a recovery system 15, an ash removal conveyor belt 8.

Each upper module 1 is provided with housing fuel supply system components, first, a fuel conveyor 40, and a cold air channel 42.

The reason for the division of the position of the upper module 1 and the lower module 2 according to the modular thermal energy complex is: the fuel is loaded into the combustion chamber 10, the combustion unit 11 of the thermal assembly 9 by gravity from top to bottom, so that the fuel supply system is located in each upper module 1 and the thermal assembly 9, the air blast system 13, the secondary air blast system 14, the recovery system 15 and the heat exchanger assembly 12 connected to the thermal assembly 9 are located in each lower module 2.

The position of the slagging conveyor 8 relative to the lower module 2 is such that slag and ash formed during combustion settles on the flat plates of the combustion chamber 10 and falls by gravity onto the slagging conveyor 8 below the combustion chamber 10. Thus, the ash and slag settle under gravity in the bottom of the filter stack 29 and the ash remover 47. The heat exchanger assembly ash remover 47 is located in each lower module 2 due to the combustion chamber 10 of the combustion unit 11 and the filter stack 29 of the heat exchanger assembly 12. Thus, ash and slag are collected in the bottom of the modular thermal energy complex design structure of the present invention, i.e. in each lower module 2.

At the position of each upper module 2, the cold air passage 42 is located, and in order to prevent the formation of condensed water in the air heater 32 in the heat exchanger assembly 12, the heater heat exchanger assembly must first preheat the cold air in the cold air passage 42 by heat exchange with the bypass air duct 27. For this purpose, a duct 43 of the cold air duct 42 is designed in the cold air duct 42 structure. Located above the combustion unit 11 and arranged to be heat-exchanged with the bypass air path 27, so that the entire cold air path is located in each upper module 2.

Meanwhile, each of the upper module 1 and the lower module 2 has a smoke exhaust system 49 and a hot gas duct 44.

The fume extraction system 49 is configured in such a way that during combustion, the fumes move from the bottom upwards. Therefore, in order to effectively collect the flue gas at the outlet of the temperature reduction chamber 18, the bypass air duct 27 and the smoke evacuation system 49 must be located above the flue gas temperature reduction chamber 18. Therefore, the combustion unit 11 is located in each lower module 2, while the bypass air duct 27 and the smoke evacuation system 49 are located in each upper module 1. At the same time, an ash remover 47 and a flue 46 connected thereto are located in each lower module 2, since a heat exchanger assembly 12 is arranged in each lower module 2. For this purpose, each lower module 2 and each upper module 1 is provided with a smoke evacuation system 49.

A hot gas path 44 is provided in each lower module 2 in such a way that the hot gas path 44 is connected to the heat exchanger package 12 in each lower module 2.

The process module 3 is electrically connected with each upper module 1 and each lower module 2, thereby realizing the control of the components of the modular thermal energy complex configuration of the invention in each lower module 2 and each upper module 1.

The modular thermal energy complex of the present invention is characterized by convenience and simplicity. The modular construction, in particular the support frame 4, provides the possibility of creating an integrated structure of a single space. Since each lower module 2 can be provided with thermal assemblies 9, the number of modules can be increased if necessary, thereby increasing the number of thermal assemblies 9 and thus the power of the modular thermal energy complex (as shown in figure 1). That is, the provision of the heat released by the modular thermal energy complex of the present invention during operation increases its efficiency and, in addition, ensures the ease of installation of the present invention. On the other hand, the single space allows free movement between the modules and unhindered maintenance of the components of the modular thermal energy complex, in particular the thermal components 9, located in the lower modules, that is to say ensures the ease of use of the invention and reduces the risk of damage to the health of the user.

The simplified design of the at least one upper module 1, the at least one lower module 2 and the process modules 3 thus allows a compact modular thermal energy complex to be obtained which is convenient for the user to use and install. The modular thermal complex can have any possible thermal power by increasing the number of modules and the configuration of the thermal assemblies, thereby increasing efficiency. The modular thermal energy complex of the invention can be used to facilitate the passage of heated air through a mine by providing the thermal module 9 and the combustion chamber 10 with solid fuel, for example, without a gas supply.

A thermal assembly 9 is provided in at least one of the lower modules 2 in the modular thermal energy complex. The thermal assembly 9 comprises: a combustion unit 11, at least one heat exchanger assembly 12, a blower system 13, a secondary blower system 14, and a recovery system 15. If the modular thermal energy complex of the present invention has more than one upper and lower module, the number of thermal modules 9 is increased by the number of lower modules 2. In this case, the number of hot gas ducts 44 also increases the number of lower modules 2, combined to form the main gas duct 56, and connected to the hot air mixing zone, thus creating a multiplication effect, increasing the efficiency of the invention and also increasing its utilization.

The combustion unit 11 of the thermal assembly 9 is a box-shaped housing 16 in which a combustion chamber 17, a solid fuel-fueled combustion chamber 10, is arranged. Any known solid fuel may be used, such as lignite, coking coal or anthracite, as well as wood or peat.

The combustion chamber 10 of the combustion chamber 17 is disposed at the bottom of the combustion chamber 17. The combustion chamber 10 of the combustion chamber 17 may be of any known construction. The combustion chamber 10 may be used as is or later. The combustion chamber 10 of the combustion chamber 17 is furthermore provided with a grate grid (not shown for convenience). The grate grid may be of any known design. For example, the grate grid may be made as strips. The grate grids may also be provided with grate grid drive means (not shown in the drawings). The drive means of the grate grid may use any known design. For example, an electric drive, such as an RGP-1 electric drive, may be used.

A flue gas temperature reducing chamber 18 is also provided inside the combustion unit 11. The combustion chamber 17 is connected with a flue gas cooling chamber 18, and the temperature of the flue gas is reduced through a filtering flue 19 and the rear wall of the combustion chamber 17.

The outer walls of the combustion chamber 17 and the flue gas temperature reduction chamber 18 may be made of any known insulator material, have a thermal conductivity of not more than 0.9 w/m, and a softening temperature of not less than 1350 ℃. Such as refractory bricks, which ensure the effectiveness of the invention.

The housing 16 of the combustion unit 11 is multi-layered and comprises at least one layer of a thermally conductive material 20, such as metal, at least one layer of a thermally insulating material 21 and a convection liner 22, as shown in fig. 6. On the one hand, the design of the device of the invention can be simplified, and on the other hand, the efficiency can be improved. The MTPMC-30 mullite siliceous material can be used as a thermal insulation material.

Meanwhile, a horizontal plate 23 may be provided on the top of the casing 16 of the combustion unit 11 as a ceiling for the combustion chamber 17 and the flue gas temperature reduction chamber 18. For example, the horizontal plate 23 may be made of concrete.

One possible embodiment is to arrange the flue 19 of the rear wall of the combustion chamber 17 in an S-shape, as shown in fig. 4. In this case, the flue 19 may be realized by two partitions 24 arranged at the edges of the combustion chamber 17 and the gas cooling chamber 18.

In the design of the claimed invention, the flue 19 in the rear wall of the combustion chamber allows for the initial removal of large particles of ash and slag from the flue. In order to collect these particles, in the flue of the gas cooling chamber 18, a particle collecting channel 25 is provided which is connected to the recovery system 15. This helps to remove ash and slag particles from the flue gas, thereby reducing the health hazard to the user.

In order to provide an ash and slag particle recovery system 15, a suitable particle feed channel 26 is provided in the design of the combustion chamber 10. The outlet of this feed channel 26 is located above the furnace floor (not shown in the drawings) and is fed to the furnace 10 through the recovery system 15 for efficient burning off of ash and slag. Thus, ash and slag particles in the flue gas are removed, thereby reducing the health hazard to the user. In addition, the efficiency of the present invention is also improved.

Meanwhile, the flue gas temperature reduction chamber 18 is provided with a duct 51 including an axial flow blower 35, and supplies air to the flue gas temperature reduction chamber 18. This is necessary to control the temperature of the air entering the at least one heat exchanger assembly 12 through the bypass air duct 27 arranged at the outlet at the top of the flue gas cooling chamber 18, and the risk of causing damage to the health of the user can be reduced.

Since the flue gas temperature reducing chamber 18 is disposed at the upper portion of the combustion unit 11, the bypass duct 27 is disposed in the structure of each upper module 1. The position of the bypass flue 27 enables efficient removal of flue gases from the flue gas cooling chamber 18, since the flue gases rise from the bottom to the top.

The bypass air duct 27 is provided with an extractor 28 effective to remove flue gases from the combustion chamber 17 passing through the flue gas temperature reduction chamber 18, the bypass air duct 27 and the at least one heat exchanger element 12 and to a stack 48, the extractor 28 being of any known construction, for example a DN-9 extractor.

The heat exchanger assembly 12 is designed to heat cold air from the atmosphere first with hot flue gases generated from the combustion chamber 17 and is arranged in each lower module 2. Further, the design of heat exchanger assembly 12 includes at least one filtered stack 29 that functions as an inertial collector (FIG. 3). The heat exchanger assembly 12, including at least one filter stack 29, ensures that ash particles supplied in the flue gas can be removed, said ash having a density of 2.5 g/cc and a diameter of more than 20 μm. The risk of health damage to the user is reduced during operation of the invention. Below the filtering flue 29 there is arranged a hopper 30 of an ash removal system, the purpose of which is to collect fine particles of ash and slag settled in the flue 29 during filtering.

As a possible alternative embodiment, the heat exchanger assembly 12 may comprise a frame 31, the frame 31 being equipped with at least two air heaters 32 and a filtering flue 29 (fig. 3) acting as an inertial collector. In various possible embodiments implementing a modular thermal energy complex, the air heater 32 may be of any known design. For example, the air heater may be sheet-like or tubular.

In various embodiments of the invention, the heat exchanger assembly 12 may be arranged in at least one lower module 2 of the modular thermal energy complex, ensuring its easy installation.

A combustion chamber blower system 13, including a ventilation duct 33 and a fan blower 34, is arranged in each lower module 2. The combustion chamber's blower system 13 is arranged to provide atmospheric air to the combustion chamber 10 through the convection liner 22 of the housing 16 of the combustion unit 11. This allows heating of the liner 22 before the atmospheric air is fed into the combustion chamber 10, thus improving the combustion efficiency of the fuel.

The secondary air blowing system 14 is an air duct for supplying air to the combustion chamber 17, and the secondary air blowing system 14 is arranged in at least one lower module 2. In this case, the side wall of the combustion chamber 17 may be provided with at least one nozzle 36. The nozzle 36 may be any known mechanical nozzle, and the secondary air blowing system 14 and the fan blower 34 are connected in order to optimize the structure of the modular thermal energy complex. Thus, the fan blower 34 is arranged to provide air to the blower system 13 and the secondary blower system 14 of the combustion unit. This allows the modular thermal energy complex of the present invention to be more simplified in design, thereby ensuring ease of installation.

A unique feature of the modular thermal energy complex system architecture of the present invention is that the thermal module 9 provides a recovery system 15 disposed in at least one of the lower modules 2. The recovery system 15 includes a return air fan 37 of any known design, such as, for example, the WWY-4, 3-3000 blower, a recovery ejector (not shown), and piping for the recovery system 15. The recovery ejector may be of any known design. For example, the ejector may use a VU recovery ejector. In addition to this, the recovery system 15 includes a particle collection passage 25 disposed in the flue gas temperature reduction chamber 18, and a supply passage 26 that supplies particles to the combustion chamber 10. The recovery system 15 is for the recovery of ash and slag which, during a first stage cleaning, is passed from the combustion chamber 17 through a flue 19 in the rear wall of the combustion chamber into a flue gas cooling chamber 18 and then back to the combustion chamber 10 by means of a return fan 37 and recovery jets (not shown). The structure of the modularized heat energy complex is greatly simplified, and the modularized heat energy complex which is more compact, simpler and more convenient to install can be realized. Furthermore, this increases the efficiency of the inventive thermal energy complex and also reduces the risk of damage to the health of the user, since it excludes ash and slag particles from entering the atmosphere.

The ash removal system is arranged in at least one lower module below the combustion unit 11. The ash removal system comprises a deslagging conveyor belt 8, a hopper 38, an ash collection tank 30 and a loading platform 39. The de-scum conveyor 8 may be of any known design. As one of the possible embodiments of the invention, the deslagging belt 8 can be a scraper.

The thermal energy complex according to the invention is provided with a fuel supply system in at least one upper module 1.

The fuel delivery system includes a hopper 40, a fuel conveyor belt 41, and a loading dock 57. And a fuel transfer belt 41 is disposed in each upper module 1. The purpose of this system is to ensure an uninterrupted delivery of fuel to the combustion chamber 17. Since the fuel supply is carried out from top to bottom under the action of gravity, a fuel delivery system is arranged in each upper module 1 above the combustion chamber 17 of the combustion unit 11 of the thermal assembly 9 arranged in turn in each lower module 2. Control of the fuel rail 41 may be effected by an automated operating system operating a touch panel located in the process module 3, or in a local state, buttons (not shown for convenience) mounted on an electric actuator. The fuel transfer belt 41 may be of any known design. The fuel transfer belt 41 may be implemented with a scraper.

At least one switch (not shown) may additionally be provided for the hopper 40 of the fuel supply system. The switch may be configured with a linear mechanism (not shown). For example, such a machine may use a MAP-style linear mechanism.

A cold air channel 42 is arranged in the at least one upper module 1, arranged to feed at least one heat exchanger assembly 12 with cold atmospheric air through a duct 43 of the cold air channel 42, as shown in fig. 5. Cold atmospheric air is supplied to the cold air duct 42 by a hot air blower 50 disposed at each lower module 2 through the cold air duct. Meanwhile, the duct 43 of the cold air path 42 can perform heat exchange with the bypass air path 27. Therefore, the preheated atmospheric air enters the at least one heat exchanger assembly 12. The hot air heater 32 of at least one heat exchanger assembly 12 is effective to add heat to increase the efficiency of the modular thermal energy complex of the present invention. In addition, such heating may avoid the formation of condensation due to the temperature differential between the heat pipes of the heat exchanger assembly 12 and the cool atmospheric air, and also improve the efficiency of the modular thermal energy complex.

The hot gas path 44 is arranged in at least one lower module 2. The hot gas path 44 is to add hot air exiting one hot gas exchanger bank 12 to a stream of cool air used for mine ventilation, for example. For this purpose, the hot gas channel 44 is provided with a switch (not shown) which can be remotely operated by means of a control button (not shown) or a dispensing device (not shown). In one possible solution for carrying out the invention, a remote switch controlling the hot gas path 44 can be provided in the process module 3. To compensate for temperature variations due to the length of the hot gas path, the hot gas path 44 may be fitted with any known thermal compensation device (not shown). For example, the hot gas path 44 may be provided with a PGVU thermal compensation device.

The modular thermal energy complex of the present invention may be provided with more than one thermal assembly 9 and more than one heat exchanger assembly 12, the hot air from each heat exchanger assembly 12 merging in a mixing zone (not shown in the drawings) through the hot gas path 44 into the path of the main air path 56 (fig. 1).

The modular thermal energy complex is further provided with a smoke evacuation system 49 arranged in at least one upper module 1 and at least one lower module 2. The smoke evacuation system 49 includes a flue 46, a bypass flue 27, at least one extractor 28, at least one ash remover 47, and a stack 48. In this case the flue gas extraction system 49 is connected in series via the bypass flue 27 and at least one heat exchanger assembly 12, the flue 46, and at least one ash remover 47. The ash remover 47 may be of any known design. An inertial ash separator may be used as an embodiment of the dust separator 47.

The smoke exhaust system 49 is thus arranged to exhaust the products of fuel combustion (flue gases) from the combustion chamber 17 through the bypass air duct 27 and the at least one heat exchanger assembly 12 via the smoke exhaust 28 through the flue 46 of the smoke exhaust system 49 to the ash remover 47 and the stack 48. To compensate for variations in flue length, the flue gas extraction system 49 may also be provided with a thermal compensation device 45 of any known construction. For example, the smoke evacuation system 49 may be provided with a PGVU thermal compensation device.

In the modular thermal energy complex of the invention, more than one thermal module 9 and more than one heat exchanger module 12 may be provided, each dust collector 47 connected to a heat exchanger module 12, unified by a chimney 48 connected to a main flue 52 through a flue 46, as shown in figure 1.

The modular thermal complex of the present invention is provided with an Automatic Control System (ACS) for controlling the blower air-blowing system 34, the return air blower 37, the hot air blower 50 and the axial flow blower 35, the combustion chamber grate drive, the combustion chamber feeding means (not shown) and the exhaust fan 28, the fuel conveyor belt 41 and the deslagging conveyor belt 8 and the switch (not shown). The automatic control system provides that if the content of carbon monoxide in hot air after the air heater exceeds the standard, hot air supply is cut off urgently, so that the safety of using the invention is ensured. In the present invention, a control center of an automated control system (ASC) is configured in the process module 3, electrically connected to each of the lower module 2 and the upper module 1.

The embodiment described in this invention to implement the apparatus is not the only possible choice but provides the most obvious way to reveal the nature of the invention.

The invention is described in detail in relation to a part of the method.

The modular heat energy complex can be used for realizing a method for heating mine air.

The solid fuel in the hopper 40 of the fuel supply system of each upper module 1 is transported to the combustion chamber 10 of the combustion chamber 17 of each lower module 2 by the fuel conveyor 41, and the fuel is burned.

At the same time, the combustion chamber 17 is supplied with air by means of a blower system 13 arranged at each lower module 2. At the same time, atmospheric air enters the blower system 13 through the exhaust generated by the hot blower system 34. The air passing through the ventilation ducts 33, the blower system 13 then enters the convection liner 22 of the housing 16 of the combustion unit 11 of each lower module 2, passes in heat exchange with the walls of the combustion chamber 10 and then enters below the grate.

Secondary air enters the combustion chamber 17 through the draft tube of the secondary air blowing system 14 by a blower air blowing system 34 provided in each lower module 2. Air from the secondary air blowing system 14 enters the combustion chamber 17 through at least one nozzle 36.

During the combustion process, flue gases are generated in the combustion chamber 17. In the flue gas heated at a high temperature (about 900 ℃) in the combustion chamber 17, under the action of vacuum generated in the smoke exhaust 28, ash and slag enter the gas cooling chamber 18 through the flue 19 formed by the partition 24 on the rear wall of the combustion chamber 17. Since these elements are all part of the combustion unit 11, they are arranged in the lower module 2.

During passage of the flue gas through the filter stack 19 in the rear wall of the combustion chamber 17, the gas flow is turned through 180 ° twice, causing a large amount of ash and slag to settle out of the flue gas, descending from the filter stack 19 in the rear wall of the combustion chamber 17 to the gas cooling chamber 18. From the gas cooling chamber 18, a large amount of ash and slag particles enter the collecting channel 25. The particles are then carried away into the recovery system 15 by a return fan 37 and a return ejector (not shown in the drawings). The particles are then transported through the particle feed channel 26 to the combustion chamber 10 of the combustion chamber 17 for combustion. The efficiency of the modular thermal energy complex of the invention is thus increased with a simplified design to reduce the risk of harm to the health of the user.

Furthermore, a partition 24 between the combustion chamber 17 and the gas cooling chamber 18 ensures circulation of flue gas in the combustion chamber 17, thereby allowing efficient combustion of the solid fuel into the combustion chamber.

After the first stage of cleaning in the gas cooling chamber 18, the flue gases are evacuated by a vacuum created by a smoke exhaust 28 through a bypass duct 27 in the upper module 1 to an air heater 32 in at least one heat exchanger assembly 12 in each lower module 2. The temperature of the flue gas entering the air heater 32 of at least one heat exchanger assembly 12 cannot exceed the allowable temperature, ensured by supplying atmospheric air (combustion chamber and secondary air blast) into the combustion chamber 17 or by operating the axial flow blower 35 (gas temperature up to emergency value) arranged in each lower module 2.

Meanwhile, the at least one air heater 32 of the at least one heat exchanger assembly 12 delivers cool air through cool air passages 42 provided in each lower module 1 and each lower module 2. The cold air channel 42 is connected to at least one heat exchanger assembly 12 by means of a hot air blower 50 arranged in each lower module 2. In this case, air enters the cold air path 42, and the duct 43 in the cold air path 42 provided in each upper module 1 is preheated by heat exchange with the bypass air path 27. The heat exchanger assembly 12 air heater 32 heats the air by the flue gas, the air being heated to about 300 ℃ by at least one heat exchanger assembly 12 air heater tube 32, which ensures the efficiency of the use of the invention if the air heater 32 is sheet-like.

At least one heat exchanger assembly 12 arranged in each lower module 2 cools the temperature of the hot flue gas to 180-190 ℃. The flue gas then passes through a filter stack 29, that is to say the flue gas is sent to a second stage for ash and slag removal. The gas flow changes the direction of travel by 180 ° in the filter stack 29 and the velocity is reduced by a factor of 2.5 due to the increase in the flow cross section. Ash particles having a density of 2.5 grams per cubic meter and a diameter greater than 20 microns fall below the filter stack 29 and settle in the ash chute 30 of the ash removal system located in each lower module 2 while maintaining the original velocity and direction. Thus, the second stage of flue gas cleaning removes ash and slag through the filter stack 29 of the at least one heat exchanger assembly 12. By reducing the amount of ash and slag entering the atmosphere, the risk of harm to the health of the user is reduced. Thereafter, the flue gas cooled to a temperature of 180-. This ensures the safe use of the invention. The flue gases are then drawn into the duct by the extractor hood 28 provided in each lower module 2 and pass to the atmosphere through a stack 48.

According to the modular thermal energy complex of the invention at least two lower level modules 2 and at least two upper level modules 1 are provided, whereby at least two heat exchanger assemblies 12 are arranged in the lower level modules 2 and flue gas cooling is conveyed from each heat exchanger assembly 12 to the ash remover 47. They precipitate the ash and slag remaining in the flue gas cooled to 180-190 ℃. A third purification stage of the flue gas is thereby achieved. The use safety of the invention is ensured. In addition, the flue gas is conveyed by the exhaust fan 28 through the flue 46 to the main flue 52 (FIG. 1) and then through the stack 48 where the flue gas enters the atmosphere.

Air heated to about 300 c by the air heater 32 of the at least one heat exchanger assembly 12 is supplied to a distribution device (not shown) via a hot gas path 44 provided in each lower module 2 as an additive to the main flow of mine ventilation air. The flow of gas inside the air heater 32 of at least one heat exchanger assembly 12, under the vacuum of the extractor 28 and the free space air under pressure from the hot air blower 50, avoids the possibility of combustion products entering the hot air and entering the mine ventilation through the hot gas path 43, ensuring efficiency and safety in the use of the thermal energy complex.

The modular thermal energy complex is provided with at least two lower level modules 2 and at least two upper level modules 1, that is, at least two heat exchanger assemblies 12 are arranged at the lower level modules 2, and hot air is introduced into the hot gas path 44 through the air heater 32. The hot air is then delivered to the main air duct 56, which is connected to the hot air duct 44, and enters the hot air mixing zone, as shown in FIG. 1. In this way, the power of the modular thermal energy complex is increased, and hot gas can be delivered into the mine, thereby achieving the efficiency of the use thereof.

The hot air mixing zone (not shown in the drawings) and the main cold air stream ventilation of the mine ventilation are heat exchanges in contact, without heat leakage through the pipes for the heating medium, the efficiency of such heat exchangers being 100%.

The integrated thermal energy system of the present invention is managed (ACS) by an automated control system that ensures control of the fan blower 34, return air blower 37, hot air blower 50 and axial flow blower 35, combustion grate drive, combustor feed (not shown for convenience), exhaust 28, fuel conveyor 41 and slagging conveyor 8 and switches (not shown for convenience). The automated integrated system provides that the hot gas supply should be switched off urgently when the carbon monoxide content in the hot air of the air heater exceeds a standard, which will reduce the risk of health damage caused when the user is using the invention. In this case, an automated integrated system is provided in the process module 3, electrically connected to each of the lower module 2 and the upper module 1.

The activity principle of the thermal energy complex therefore comprises: the hot flue gases produced in the thermal module 9 are obtained and fed to at least one heat exchanger module 12, heated atmospheric air is sent to the main ventilation blower of the mine ventilation by means of a pressurized hot air blower 50 and a distribution device (not shown) for the supply of hot air.

For the purpose of the invention to facilitate installation, each lower module 2 and at least one process module 3 are mounted on a base 6 having a recess 7. The arrangement of the deslagging belt 8 in the grooves 7 then ensures an efficient collection of the ashes and slags, that means the effectiveness of the invention in terms of reducing the risks of harm to the health of the user.

The embodiment of the method described herein is not the only alternative, in order to most clearly disclose the nature of the invention.

The modular thermal energy complex of the present invention is compact and easy to install and use. The risk that the multi-layer flue gas purification system causes harm to the health of users in the using process is reduced, the combustion chamber of the heat energy complex utilizes solid fuel, and the invention is indispensable under the condition of no natural gas supply and can be realized by industrial production.