KR102345871B1 - Hybrid power generation system using forest residues - Google Patents

Abstract

The present invention relates to a hybrid power generation system using forest residues (1), wherein the system comprises: a carbonization unit (10); a cooling unit (20); an exhaust unit (30); a heat source unit (40); and a supply unit (50). According to the present invention, it is possible to greatly reduce environmental pollution, and at the same time, to provide an effect of greatly enhancing power generation efficiency.

Description

Hybrid power generation system using forest residues

The present invention relates to a hybrid power generation system using a heat source such as gas, which is inevitably generated in the carbonization process of forest residues, and more specifically, to a desired form through the carbonization process of forest residues (bio-mass) from jungle areas. While continuously generating a predetermined fuel of The power generation efficiency can be greatly increased through the recycling of biomass in various ways by operating It relates to a hybrid power generation system using forest residues.

In general, in the cultivation of agricultural products in greenhouses or houses, it is common for workers to directly approach the cultivation facilities, observe the growth status of agricultural products, and adjust the growth conditions for agricultural products by manipulating the facilities. In addition, crop workers need to know the overall cultivation method well, and various efforts such as work activities that are close to heavy labor and require a lot of time are required. And these days, although the function of greenhouses is improving more and more, along with this, crops often suffer from high temperature and low temperature failures due to careless operation of facilities or defects in control devices, so more experience is required. It is also As such, in recent years, smart agricultural production systems based on sensors and networks have created an optimal environment based on management of various information such as temperature, humidity and carbon dioxide (CO2) from the growth and growth stages of agricultural products, and to reduce damage from pests and diseases. A smart farm, where even beginners can easily grow agricultural products, is installed and managed more meticulously. the current situation.

For example, according to Korean Patent Application Laid-Open No. 2020-0094302, 'a farm room 100 that forms a space blocked from outside air to facilitate the creation of a palm material environment, and a farm that forms a cultivation space in which soil is contained so that crops can be cultivated. A planter 110, a palm exposure sensor 111 that is installed closest to the soil where cultivation is made at the upper end of one side of the palm pot 110, is fitted from the side of the palm pot 110 to detect the humidity of the cultivated soil According to a signal input through the palm humidity sensor 112, the carbon dioxide sensor 111b for detecting the surrounding carbon dioxide concentration of the palm pot 110, the palm exposure sensor 111 and the palm humidity sensor 112, The palm control unit 120 that controls the cultivation, the palm lighting unit 121 that is turned on according to the control of the farm control unit 120, and the palm planter 110 according to the control of the farm control unit 120 supply moisture to the soil a palm pump 122 to, a palm water storage unit 122a in which water for pumping of the palm pump 122 is stored, and a palm water pipe supplying water pumped by the palm pump 122 to the palm potting plant 110 (122b), the water supplied from the palm water supply pipe (122b) is composed of a palm water supply distribution pipe (122c) and a palm water supply nozzle (122d), and the palm room 100 is arranged such that a plurality of palm planters 110 are arranged. a cell unit, and a ventilation fan 101 is configured in the palm room 100 to ventilate indoor air according to the sensor's detection value, and the ventilation fan 101 is the opposite amount of the palm room 100 . It is formed on the wall so that the supply of outside air and the discharge of the bet are made, and the palm exposure sensor 111, the palm humidity sensor 112, and the carbon dioxide sensor 111b configured around the palm flowerpot 110 are modularized to It is configured to be easily mounted on the palm planter 110, and the palm control unit 120 is composed of an input unit 120a and an output unit 120b. Depending on the sensor value input to the input unit 120a, the palm lighting unit 121 and A smart farm, characterized in that configured to drive and control the palm pump 122.' is presented.

However, the smart farm described above has a problem in that a large amount of cost may occur because heating must be performed through a separate fuel in order to drain hot water and the like.

As another example, according to Korean Patent Registration No. 1802376, 'energy demand department including livestock barns, vertical farms, and houses; An anaerobic unit generating methane and carbon dioxide by fermenting waste and organic matter transferred from livestock, vertical farm, and housing, a separation unit separating methane and carbon dioxide transferred from the anaerobic unit, respectively, methane separated from the separation unit a by-product gas generating unit including a methane storage unit and a carbon dioxide storage unit in which carbon dioxide is stored, respectively; a solar/wind hybrid power generation device for supplying power generated using solar heat and wind power to the energy demand unit; a solar power generation device for supplying power generated using sunlight to the energy demand unit; a waste heat supply unit for transferring the waste heat generated by the solar/wind power hybrid power generation device and the solar power generation device to the anaerobic unit; The upper surface is opened, the water tank is stored therein; a solar heat absorption film that seals the upper surface of the water tank and absorbs solar heat and transfers it to the water filled in the water tank to promote water vaporization; a wind power generator comprising a fixed shaft hinged to the solar heat absorbing film, a blade coupled to the center of the fixed shaft and rotated by wind power, and a wind power generating box converting rotational energy of the blade into electrical energy; an injector coupled to the lower part of the wind power generator and including an inlet through which steam rising from the inside of the water tank is introduced, and a discharge nozzle through which the steam stored in the inlet is discharged in a direction opposite to the rotation of the blade; A condensing lens for condensing sunlight, a driving shaft to which the condensing lens is coupled and generating steam by sunlight collected by the condensing lens, and rotating the driving shaft according to the trajectory of the sun so that the condensing lens faces the sun Solar tracker including a sun tracking sensor; a heating wire coupled to the drive shaft and installed to penetrate the inside of the water tank and the inside of the fixed shaft, and transferring the steam generated by the drive shaft to water stored in the water tank and steam rising from the inside of the fixed shaft; a steam generator communicating with an upper portion of the fixed shaft and generating electricity by steam rising from the inside of the fixed shaft; a return pipe communicating the upper end of the fixed shaft and the inside of the water tank and allowing the steam rising from the upper portion of the fixed shaft to return to the inside of the water tank; a Stirling engine communicating with the return pipe and generating electricity by steam flowing from the return pipe; and an external combustion engine that is in communication with the return pipe and is generated by steam flowing from the return pipe; it includes, a farm installed on each floor, supported by a truss structure, and the outer wall is filled with carbon dioxide or argon gas, such as a transparent rectangular balloon A smart farm system equipped with a greenhouse or greenhouse insulated with the insulation of

However, such a solar/wind power hybrid power generation device and a smart farm system including the same also aim to be used through a heat source using solar heat and wind power, but there is a disadvantage in that more facilities and costs are added to obtain a heat source.

Korean Patent Publication No. 2020-0094302 "Smart Farm" Korean Patent No. 1802376 "Solar/wind hybrid power generation device and smart farm system including the same"

It is an object of the present invention to fundamentally improve the problems of the prior art, while continuously generating a predetermined fuel in a desired form through the carbonization process of forest residues (bio-mass) from jungle areas, etc. , by compressing and burning various types of waste gases generated when heating for carbonization of forest residues, greatly reducing environmental pollution such as air and operating a steam boiler at the same time, By providing hot water and electricity to farms such as plastic houses and smart farms, we provide a hybrid power generation system using forest residues to greatly increase power generation efficiency through multi-faceted recycling of bio-mass. is about to do

In the present invention for achieving the above object, in constructing a hybrid power generation system using forest residues: After accommodating the forest residues to be formed in a double structure so as to be heated while accommodating the forest residues, by a moving screw It is formed in a double structure of an inner cylinder to move forward and an outer cylinder having an ignition part so that heat can be applied to forest residues in the state that the inner cylinder is accommodated. a carbonization unit in which a heating space is formed; It has a discharging unit to generate appropriately carbonized carbide in the form of a set pellet through heating of the carbonized unit, and a rotating screw that allows the heated forest residue to be moved while accommodating it, and a flow path and mounted at equal intervals a cooling unit having a cooling ring to be formed, a nozzle disposed on the cooling ring, and a spray controller for controlling a spray state of the cooling medium through the nozzle; an exhaust unit having an exhaust pipe to discharge waste gas generated from forest residues heated while communicating with the carbonization unit; As the cooling part and the exhaust part communicate with each other organically, the cooling part and the exhaust part communicate with each other so that heating is possible by waste gas or pellet-type carbide. Provided with a hybrid steam boiler designed to do this, but after applying initial preheating to a temperature of 500 to 550 ° C using pellet-type carbide, and then heating it to a temperature of 650 ° C or higher using waste gas, it is automatically continuously heated to 700 to 800 a heat source unit having a separate temperature sensor to sense the temperature while maintaining the temperature at ℃; and a supply unit that communicates with the heat source unit and supplies heat, hot water, and electricity to a smart farm or a plastic house through a hybrid steam boiler.

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In addition, the supply unit of the present invention is operated by converting high heat energy generated from the hybrid steam boiler into mechanical energy while communicating with the heat source, while accumulating electricity production by a turbine and a turbine that supplies warm and hot water to the smart farm. It is characterized in that it is further provided with a generator to enable it.

On the other hand, prior to this, the terms or words used in the present specification and claims should not be construed as being limited to conventional or dictionary meanings, and the inventor should understand the concept of the term in order to explain his invention in the best way. Based on the principle that it can be appropriately defined, it should be interpreted as meaning and concept consistent with the technical idea of the present invention. Therefore, the embodiments described in this specification and the configurations shown in the drawings are only the most preferred embodiment of the present invention, and do not represent all the technical spirit of the present invention, so at the time of the present application, various It should be understood that there may be equivalents and variations.

According to the present invention, a predetermined fuel in a desired shape is continuously generated through the carbonization process of forest residues (bio-mass) coming from forest areas, etc., while heating for carbonization of forest residues. By compressing and combusting various types of waste gases generated at the same time, it greatly reduces environmental pollution such as air and operates a steam boiler. By allowing it to be provided to the farm, it provides the effect of greatly increasing the power generation efficiency through the multi-faceted recycling of biomass.

1 is a diagram showing the overall configuration of a hybrid power generation system using forest residues according to the present invention.
2 is an enlarged view showing the carbonization part of the hybrid power generation system using forest residues according to the present invention.
3 is an enlarged view showing the cooling unit of the hybrid power generation system using forest residues according to the present invention.
4 is an enlarged view showing the heat source and power generation of the hybrid power generation system using forest residues according to the present invention.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings.

The present invention relates to a hybrid power generation system using a heat source obtained from forest residues (1), and includes a carbonization unit (10), a cooling unit (20), an exhaust unit (30), a heat source unit (40), a supply unit (50), etc. as the main component.

The carbonization part 10 according to the present invention is formed in a double structure so that heating is possible while accommodating the forest residue 1 . After introducing the forest residues 1 from finely cut trees and shrubs into the carbonization unit 10, they are heated within as short a time as possible to sequentially perform carbonization through thermal decomposition. In the carbonization unit 10, the wood cut to a predetermined size or less is put through a separate crushing unit (not shown) without putting the whole tree.

At this time, the carbonization unit 10 has an inner cylinder 12 that accommodates the forest residue 1 and then moves by the moving screw 11 , and the forest residue in a state accommodating the inner cylinder 12 . Forming two or more heating spaces by using one or more bulkhead plates 15 having a dual structure of an outer cylinder 14 having an ignition part 13 to apply heat to (1), and having thermal insulation properties characterized. That is, the carbonization unit 10 is formed in a double structure of the inner cylinder body 12 and the outer cylinder body 14, and the forest residue 1 injected into the inner cylinder body 12 through the moving screw 11 is a cooling unit to be described later. On the other hand, the inner cylinder 12 is accommodated inside the outer cylinder 14 while the outer cylinder 14 is wrapped around the outside of the inner cylinder 12 . And between the inner cylinder 12 and the outer cylinder 14, since the entire outer surface of the inner cylinder 12 is evenly heated through a separate ignition unit 13, the forest residue that is accommodated in the inner cylinder 12 and moved Water (1) is sequentially carbonized and gradually thermally decomposed. And, by maintaining the shape of the outer cylinder 14 divided into separate partition plates 15 , sequential thermal decomposition is individually performed through the ignition units 13 of different temperatures.

In addition, the cooling unit 20 according to the present invention is provided with a discharge unit 22 so that the carbide 21 appropriately carbonized through the heating of the carbonization unit 10 is generated in a set pellet form. do. The cooling unit 20 communicates with the carbonization unit 10 to form the carbide 21 of the forest residue 1 subjected to thermal decomposition in the carbonization unit 10 . The cooling unit 20 lowers the temperature of the forest residue 1 by spraying a separate cooling medium, and discharges it through the discharge unit 22 so that the carbide 21 is formed.

At this time, the cooling unit 20 includes a rotating screw 23 that accommodates and moves the heated forest residue 1 , a cooling ring 24 mounted at equal intervals, and a cooling ring 24 . It is characterized in that it is composed of a nozzle (25) arranged and a spray controller (26) for controlling the spray state of the cooling medium through the nozzle (25). The cooling unit 20 moves the pyrolyzed forest residue 1 through the rotary screw 23 and continuously sprays a cooling medium to the moving forest residue 1 through the nozzle 25. A ring 24 is formed. And the cooling ring 24 is interlocked with the spray controller 26 to lower the temperature of the forest residue 1 to an appropriate temperature while allowing the carbide 21 in the form of pellets to be generated at the downstream end, and this discharge unit ( 22) to allow various types of carbides 21 to be discharged.

In addition, the exhaust unit 30 according to the present invention is provided with an exhaust pipe 31 to discharge various waste gases 2 generated from the forest residue 1 heated while communicating with the carbonization unit 10 . The exhaust part 30 communicates with the inner cylinder 12 of the above-described carbonization part 10 and exhaust pipe ( 31) is provided. The exhaust pipe 31 is suitably formed so that two or more heating spaces are formed using the above-described partition plate 15 so as to be able to communicate with each individual heating space.

In addition, the heat source unit 40 according to the present invention is a hybrid steam boiler 41 so that the cooling unit 20 and the exhaust unit 30 communicate with each other to enable heating through the waste gas 2 or the carbide 21 . be prepared A hybrid steam boiler 41 capable of heating is formed in the heat source unit 40 , and the hybrid steam boiler 41 communicates with the exhaust unit 30 and the cooling unit 20 with each other. It has a configuration that is heated by supply of waste gas (2) or carbide (21) of the cooling unit (20).

At this time, in the hybrid steam boiler 41 of the heat source part 40, the cooling part 2 and the exhaust part 30 communicate with each other, so that the initial preheating through the carbide 21 and continuous heating through the waste gas 2 are performed. It is characterized in that it is possible. That is, in the hybrid steam boiler 41 of the heat source part 40, the cooling part 20 and the exhaust part 30 are formed in communication with each other. In order to operate the hybrid steam boiler 41, the waste gas 2 and The carbide 21 is used. In more detail on this part, first, the hybrid steam boiler 41 is first heated through the carbide 21 flowing in from the cooling unit 20 so that it can be operated through the initial preheating, and then the carbonization unit ( 10) is configured to enable continuous heating while the waste gas 2 of the forest residue 1 generated in the carbonization process is introduced from the exhaust unit 30 .

In addition, initial preheating is applied to the hybrid steam boiler 41 of the heat source unit 40 to a temperature of 500 to 550° C. through the carbide 21, and heated to a temperature of 650° C. or higher through the waste gas 2, and the Thereafter, the temperature of 700 to 800° C. is maintained while automatically continuously heating, and at this time, a temperature sensor 42 is further provided to detect this temperature. As such, the hybrid steam boiler 41 of the heat source unit 40 enables heating using the waste gas 2 and the carbide 21, and is configured to enable primary initial preheating and secondary continuous heating. In addition, the initial preheating refers to what is generated during the initial operation of the hybrid steam boiler 41, and the continuous heating refers to operating to maintain the elevated temperature when a constant temperature is reached after the initial operation. That is, the hybrid steam boiler 41 performs heating with any one of the waste gas 2 and the carbide 21, but in order to further increase the thermal efficiency, it generally uses the carbide 21 having a high calorific value from 500 to The initial preheating is started so that the temperature can be 550 ° C. After that, although the calorific value is lower than that of the carbide 21, the waste gas 2 of the carbonization process obtained by heating the forest residue 1 for a long time is collected and heated to 700~ Make sure to keep the temperature around 800℃. And as the height is sensed through a separate temperature sensor 42 , the hybrid steam boiler 41 may be configured to utilize any one of the waste gas 2 and the carbide 21 well.

In addition, the supply unit 50 according to the present invention supplies heat, hot water, and electricity to the smart farm 51 through the hybrid steam boiler 41 while communicating with the heat source unit 40 . The supply unit 50 uses the heat as it is through the high heat generated from the hybrid steam boiler 41 of the heat source unit 40 or heats the hot water through the high heat, and through this, the hot water is supplied to the smart farm 51. Accordingly, the appropriate temperature of the smart farm 51 can be raised or maintained. Thereby, it is possible to significantly reduce the damage of high temperature or low temperature disturbance of crops, and it is possible to maintain the optimum temperature through the above-described supply unit 50 .

On the other hand, the supply unit 50 communicates with the heat source unit 40 and converts high heat energy generated from the hybrid steam boiler 41 into mechanical energy to operate, while supplying warm and hot water to the smart farm 51 . It is characterized in that it further includes a generator 53 to enable electricity production and electricity accumulation by the turbine 52 and the turbine 52 . The supply unit 50 communicates with the heat source unit 40 and converts high heat energy generated from the hybrid steam boiler 41 into mechanical energy while providing a turbine 52 for supplying warm and hot water to the smart farm 51, The generator 53 operated through the turbine 52 generates electricity and accumulates electricity at the same time, thereby providing bright light in the smart farm 51 or in the plastic house. That is, the turbine 52 operates the generator 53 while providing hot and hot water heated from the hybrid steam boiler 41 to the smart farm 51 , and the electricity accumulated in the generator 53 is stored in the smart farm 51 . ) or as another separate source. In addition, when the operation of the carbonization unit 10 is difficult, heat, hot water, and electricity may be supplied to the smart farm 51 by operating the turbine 52 through the electricity accumulated in the generator 53 . In addition, in the hybrid steam boiler 41, a turbine 52 and a generator 53 are normally built-in, but in some cases, a turbine 52 and a generator 53 are additionally installed on the outer surface of the hybrid steam boiler 41. states that it is possible

According to the present invention, a predetermined fuel in a desired shape is continuously generated through the carbonization process of forest residues (bio-mass) coming from forest areas, etc., while heating for carbonization of forest residues. By compressing and combusting various types of waste gases generated at the same time, it greatly reduces environmental pollution such as air and operates a steam boiler. By allowing it to be provided to the farm, it provides the effect of greatly increasing the power generation efficiency through the multi-faceted recycling of biomass.

The present invention is not limited to the described embodiments, and it is apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the present invention. Accordingly, it should be said that such variations or modifications fall within the scope of the claims of the present invention.

1: Forest residue 2: Waste gas
10: carbonization part 11: moving screw
12: inner cylinder 13: ignition unit
14: outer cylinder 15: bulkhead plate
20: cooling unit 21: carbide
22: discharge part 23: rotary screw
24: cooling ring 25: nozzle
26: spray controller 30: exhaust
31: exhaust pipe 40: heat source part
41: hybrid steam boiler 42: sensor
50: supply unit 51: smart farm
52: turbine 53: generator

Claims (6)

In constructing a hybrid power generation system using forest residues (1):
An inner cylinder 12 that accommodates the forest residue 1 to be formed into a double structure to be heated while receiving the forest residue 1, and then moves forward by the moving screw 11, and this inner cylinder ( 12) is formed in a double structure of the outer cylinder body 14 having an ignition part 13 so that heat can be applied to the forest residue 1 in a state containing 12), and one or more bulkhead plates 15 having thermal insulation properties a carbonization unit 10 in which two or more heating spaces are formed by using;
It is provided with a discharge unit 22 so that the carbonized carbide 21 is appropriately produced in the form of a set pellet through the heating of the carbonized unit 10, and can be moved in a state containing the heated forest residue 1 The spraying state of the cooling medium is controlled through the rotating screw 23 that allows the a cooling unit 20 having a spray controller 26 to adjust;
an exhaust unit 30 having an exhaust pipe 31 to discharge the waste gas 2 generated from the forest residue 1 heated while communicating with the carbonization unit 10;
The cooling unit 20 and the exhaust unit 30 communicate with each other so that the cooling unit 20 and the exhaust unit 30 are in organic communication with each other, and the cooling unit 20 and the exhaust unit 30 are in communication with each other so that heating is possible by the waste gas 2 or the carbide 21 in the form of pellets. A hybrid steam boiler 41 is provided that enables continuous heating by using the waste gas 2 together with initial preheating using the carbide 21 in the pellet form, but 500 ~ using the carbide 21 in the pellet form. After initial preheating to a temperature of 550°C, the waste gas (2) is used again to heat to a temperature of 650°C or higher, and automatically and continuously heated to maintain the temperature of 700-800°C. Separately to detect the temperature a heat source unit 40 having a temperature sensor 42 of; and
Forest residue characterized in that it comprises a; while communicating with the heat source unit 40, the supply unit 50 for supplying heat, hot water, and electricity to the smart farm 51 or the plastic house through the hybrid steam boiler 41 Hybrid power generation system using delete delete delete delete According to claim 1,
The supply unit 50 communicates with the heat source unit 40 and converts high heat energy generated from the hybrid steam boiler 41 into mechanical energy to operate, while a turbine that supplies hot and hot water to the smart farm 51 ( 52) and a hybrid power generation system using forest residues, characterized in that the generator (53) is further provided to enable the accumulation of electricity production by the turbine (52).

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