KR101453611B1 - Energy harvesting system using fermentation heat - Google Patents

Abstract

The energy harvesting system using the fermentation heat according to an embodiment of the present invention includes a fermentation tank having a closed inner space and generating fermentation heat in the inner space, a thermally conductive material immersed in the fermentation tank to transfer fermentation heat, And an engine driven by the fermentation heat transferred from the heat conductor. The power can be generated by moving the piston inside the engine by the fermentation heat transferred from the heat conductor.

Description

TECHNICAL FIELD [0001] The present invention relates to an energy harvesting system using a fermentation heat,

The present invention relates to an energy harvesting system using fermentation heat, and more particularly, to an energy harvesting system using a fermentation heat to generate power by operating a stirling engine using fermentation heat.

As the population grows, wastes such as food or livestock manure are also increasing as a by-product. In the face of the problem of energy exhaustion at the urgent point of searching for the treatment method, much research has been conducted to reduce energy loss. Related to this, biomass energy and waste energy can be considered as renewable energy.

In biomass energy, biomass refers to organisms such as plants and microorganisms that are used as energy sources and can pyrolyze or ferment these organisms to obtain fuels such as methane, ethanol, and hydrogen, that is, biomass energy. For example, in dry biomass such as wood, combustible gas can be collected by gasification or pyrolysis, and methane gas can be obtained by anaerobic fermentation in waste liquid, dirt, seaweed, etc., and alcohol can be obtained from sweet potatoes .

Examples of methods of using such biomass as an energy source include direct combustion, methane fermentation, and alcohol fermentation. For example, when organisms decay in the absence of air, methane gas is generated. This process is called inorganic respiration. The generated methane gas, ie, biogas, can be used as a fuel for cooking, heating, and the like.

In addition, waste energy refers to the energy obtained by changing the waste, and it can be said that the waste of high energy content among the combustible wastes generated in the workplace or the home is decomposed by pyrolysis, the manufacturing technology of molded solid fuel, It also produces solid fuel, liquid fuel, gaseous fuel, and waste heat through processing and treatment methods such as heat recovery technology by incineration, so that the energy required for industrial production activities can be utilized.

Such waste energy or biomass energy is recycled waste resources, so it has a great advantage in that it can reduce fuel cost burden, increase energy efficiency, and is economical and can prevent environmental pollution. Therefore, have.

An object of the present invention is to provide an energy harvesting system using a fermentation heat that can realize a more efficient energy cycle using not only gas generated from waste but also fermentation heat.

An object of the present invention is to provide an energy harvesting system using a fermentation heat that can be additionally installed in an existing waste disposal facility as well as installing a separate waste disposal apparatus.

According to an embodiment of the present invention, there is provided an energy harvesting system using environmentally friendly, efficient, and fermentation heat by reducing the emission of noise and atmospheric pollutants by using a Stirling engine.

According to an embodiment of the present invention, there is provided an energy harvesting system using a fermentation heat, comprising: a fermentation tank having a closed internal space to generate fermentation heat in the internal space; a thermally conductive body immersed in the fermentation tank to transfer fermentation heat; And an engine that is connected to the heat conductor and driven by the fermentation heat transferred from the heat conductor. The power can be generated by moving the piston inside the engine by the fermentation heat transferred from the heat conductor

According to one aspect of the present invention, a plurality of heat conductors are provided, and the engine is provided in a number corresponding to the number of the heat conductors, and one engine corresponding to each of the heat conductors can be connected.

According to one aspect of the present invention, a plurality of heat conductors are provided, and the engine is provided in a smaller number than the number of the heat conductors, so that a plurality of heat conductors can be connected to one engine.

According to one aspect of the present invention, the engine is a stirling engine, the stirling engine includes a cylinder connected to the heat conductor and to which ferroelectric heat is transferred from the heat conductor, a piston disposed inside the cylinder and moved by the fermentation heat, A radiator for radiating heat to the outside and a supplement for assisting heat dissipation to the outside.

According to one aspect, the other end of the engine may be connected to a generator or a battery.

According to one aspect, the heat conductor has a protruding end, and the protruding end can be immersed in the fermenter.

According to the energy harvesting system using the fermentation heat according to one embodiment, a more efficient energy cycle can be realized by using not only the gas generated from the waste but also the fermentation heat.

According to the energy harvesting system using the fermentation heat according to one embodiment, not only a separate waste disposal apparatus but also an existing waste disposal facility can be additionally installed and utilized.

According to the energy harvesting system using the fermentation heat according to one embodiment, the emission of noise and atmospheric pollutants can be reduced by using the stirling engine, and the environment-friendly and efficiency can be improved.

1 is a perspective view of a fermenter in an energy harvesting system using a fermentation heat according to an embodiment.
FIG. 2 is a view illustrating an energy harvesting system using a fermentation heat according to an embodiment in which an engine is installed in a fermenter viewed from above.
FIG. 3 is a view showing an engine and a conductor installed in an energy harvesting system using a fermentation heat according to an embodiment.
FIG. 4 illustrates a structure of a stirling engine in an energy harvesting system using a fermentation heat according to an embodiment.
FIG. 5 illustrates an overall energy production process by an energy harvesting system using a fermentation heat according to an embodiment.

Hereinafter, embodiments according to the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to or limited by the embodiments. Like reference symbols in the drawings denote like elements.

FIG. 1 is a perspective view of a fermenter in an energy harvesting system using a fermentation heat according to an embodiment, FIG. 2 is a view showing an engine installed in a fermenter seen from above in an energy harvesting system using a fermentation heat according to an embodiment, FIG. 4 illustrates a structure of a stirling engine in an energy harvesting system using a fermentation heat according to an embodiment, and FIG. 5 illustrates a structure of a stirling engine in an energy harvesting system using a fermentation heat according to an embodiment. The overall energy production process in the energy harvesting system using the fermentation heat according to the embodiment is shown.

1 to 5, an energy harvesting system 100 using a fermentation heat according to an embodiment may include a fermenter 110, a heat conductor 120, and an engine 130.

The fermenter 110 is a container for fermentation, and may have a closed internal space. Although the fermenter 110 is illustrated as having a cylindrical hemispherical lid, the present invention is not limited thereto, and the fermenter 110 may include a spherical shape, a cone shape, or the like.

Also, although not shown, the fermentation tank 110 may be equipped with metering devices such as piping or device for heating sterilization, cooling, ventilation, agitation, and pressure gauge.

Wastes such as food, sewage sludge, or animal manure can be introduced into the inner space of the fermentation tank 110 and fermented. At this time, while the wastes ferment, gas or fermentation heat may be generated. For example, an oxygen-free anaerobic environment may be formed in the closed fermentation tank 110 to decompose the wastes by microbial action to generate methane gas or fermentation heat.

Further, since the fermentation heat is continuously generated in the fermentation tank 110 as the waste flows into the fermentation tank 110, the energy can be continuously obtained using the fermentation heat. In addition, for example, if a single heat is generated in the waste treatment process, it may be maintained for about 2-3 days. Therefore, energy harvesting is continuously performed by introducing the waste into the fermenter 110 at intervals of 2-3 days .

The heat conductor 120 may be immersed into the closed space of the fermenter 110. [

Since the thermoconductor 120 transmits fermentation heat generated during fermentation of waste in the fermentation tank 110, it is preferable that the thermoconductor 120 is selected from a material having a high thermal conductivity.

Here, heat conduction refers to the phenomenon that the heat inside the object is transferred from one part to another part adjacent to it by molecular motion, and gold, silver, bronze, nickel or lead .

Also, the heat conductor 120 has a protruding end, so that the protruding end can be immersed in the fermenter 110. Since the cross-sectional area of the end portion of the heat conductor 120 is increased through the protruding end portion, the fermentation heat generated in the fermentation tank 110 can be transferred to the upper portion of the fermentation tank 110 more quickly. For example, if other conditions including the generated fermentation heat and the material of the heat conductor 120 are the same, the larger the cross-sectional area, the faster the heat transfer rate can be. In addition, the protruding end can easily enter the wastes in the fermentation tank 110, so that more fermentation heat can be transferred through the heat conductor 120. [ Although the protruding end portion is shown in a pointed shape in the drawing, the protrusion end portion is not limited thereto, and the protruded end portion may include a pointed shape, a thin shape, and the like.

In addition, a plurality of heat conductors 120 may be provided. Although a plurality of heat conductors 120 radially disposed from the center of the fermenter 110 are shown in the drawings, the heat conductors 120 may be provided in various arrangements including a plurality of rows or columns parallel to each other. The provision of the plurality of heat conductors 120 as described above is advantageous in that the fermentation heat generated in the fermentation tank 110 can be transmitted more quickly and more than when one heat conductor 120 is used. By providing the heat conductor 120 in this manner, the fermentation heat can be efficiently transferred from the fermentation tank 110 to the engine 130, thereby realizing a more efficient energy harvesting system 100.

The engine 130 may be connected to the opposite side of the protruding end of the heat conductor 120.

The engine 130 may be a stirling engine. In the following description, the engine 130 will be described using a stirling engine as an example.

The Stirling engine is a closed type external combustion engine that operates using the temperature difference inside the engine and can have the highest thermal efficiency in the thermodynamic theory. Moreover, since there is no explosion stroke at the time of combustion, engine vibration and noise are low, and because it is an external combustion engine, it is a heat engine that can utilize all heat sources such as waste heat and solar heat as well as fossil fuel.

The stalling engine may include a cylinder 132, a piston 134, and a radiator 136.

The cylinder 132 may be connected to the heat conductor 120 to transmit the fermentation heat from the heat conductor 120. Accordingly, one end of the cylinder 132 to which the heat conductor 120 is connected may exhibit a high temperature due to the fermentation heat, and the other end of the cylinder 132 opposite to the heat conductor 120 may exhibit a relatively low temperature. As described above, a temperature difference may occur in the cylinder 132 due to the fermentation heat.

Further, the piston 134 can be disposed and moved inside the cylinder 132. [ Specifically, when the gas inside the cylinder 132 is heated and expanded by the fermentation heat transferred from the fermentation tank 110, the piston 134 is heated from the fermentation tank 110 to the outside or through the heat conductor 120 Can be extended and moved in the direction in which the conductive material is conducted. For example, the piston 134 can be moved by the difference between the temperature inside the initial cylinder 132, i.e., the temperature raised by the external temperature and the fermentation heat.

Further, the radiator 136 may be disposed outside the cylinder 132 to dissipate the heat inside the cylinder 132 to the outside. If the heat inside the cylinder 132 is left unchanged, the temperature difference between both ends of the cylinder may be reduced due to continuous supply of the fermentation heat, which may reduce the efficiency. The radiator 136 is disposed outside the cylinder 132 to dissipate the heat inside the cylinder 132 to the outside, so that the temperature difference between the both ends of the cylinder 132 can be kept larger.

Here, the stirling engine may include a supplement (not shown) for assisting heat dissipation to the outside, and when a gas having a high thermal conductivity is used as a supplement to the radiator side, the temperature difference between both ends of the cylinder becomes larger and the efficiency can be further increased. As a result, the gas inside the cylinder 132 which has been expanded by the fermentation heat shrinks while the temperature is lowered, and the piston 134 can be moved toward the internal space of the fermentation tank 110 or toward the heat conductor 120.

As described above, the expansion and contraction of the gas inside the cylinder 132 repeatedly occur, and the stirling engine can be operated. In other words, the operation of the stirling engine can be started from a point in time when a temperature difference between the fermentation heat generated in the fermentation tank 110 and the outside air occurs. The greater the degree of temperature rise due to the fermentation heat, the higher the thermal conductivity of the gas used as a supplement to the radiator side, the greater the expansion and contraction of the gas in the cylinder 132, and the more power can be generated from the stirling engine.

Briefly, with this configuration, the Stirling engine can be operated as follows.

The fermentation heat generated from the fermentation tank 110 can be transferred to the cylinder 132 of the stirling engine through the heat conductor 120. Thereafter, the temperature inside the cylinder 132 is raised by the fermentation heat, so that the gas inside the cylinder 132 can be heated and expanded. The piston 134 is moved in the opposite direction of the heat conductor 120 by the expanded gas. At this time, heat is radiated to the outside by the radiator 136 provided outside the cylinder 132, and the temperature inside the cylinder 132 can be reduced. As a result, the gas inside the cylinder 132 is contracted and the piston 134 moves toward the heat conductor 120. By the repeated movement of the piston 134 due to the expansion and contraction of the gas inside the cylinder 132, the stirling engine can be operated, thereby generating power.

A plurality of stuttering engines may be provided.

As described above, the heat conductor 120 or the stuttering engine can be provided in plural and can be connected as follows.

For example, the heat conductor 120 and the stuttering engine may be provided in the same number, so that one stator engine may be connected to each of the heat conductors 120. Here, the heat conductor 120 and the stirling engine can be matched one to one. Alternatively, the stuttering engine may be provided in a smaller number than that of the heat conductor 120, so that a plurality of heat conductors 120 may be connected to a single Stirling engine. In this way, since more heat is transferred from the plurality of heat conductors 120, the temperature rise width of the cylinder 132 of the stirling engine becomes larger, and the movement width of the piston 134 also becomes larger. Thereby, more power can be obtained from the Stirling engine.

By using the stirling engine in the energy harvesting system 100 using the fermentation heat according to one embodiment, unnecessary noise and emission of air pollutants can be reduced. For example, it is possible to reduce NOx and SOx emissions from combustion in a conventional diesel power generation system, thereby reducing the amount of material that affects global warming. Thus, a relatively environmentally friendly energy harvesting system can be provided.

With this arrangement, the energy harvesting system 100 using the fermentation heat according to one embodiment can be specifically operated as follows.

First, waste containing food waste, sewage sludge, livestock manure, etc. is introduced into the fermentation tank 110. As such wastes are fermented in the fermentation tank 110, a gas containing methane gas or a fermentation heat can be generated.

At this time, the gas generated from the fermentation tank 110 is transferred to the heat exchanger including the boiler, and can generate electricity using the steam generated in the heat exchanger. This process is generally a process in which energy is acquired from waste and is generated.

However, energy can be obtained using an energy harvesting system using the temperature difference from the fermentation heat generated from waste that can be disposed of.

Specifically, the fermentation heat generated from the fermentation tank 110 can be transferred to the heat conductor 120 immersed in the fermentation tank 110. Here, by immersing the plurality of heat conductors 120, more fermentation heat can be transferred from the fermentation tank 110. Further, by selecting a material having a high thermal conductivity as the heat conductor 120, it is possible to deliver more fermentation heat faster.

The heat transferred from the heat conductor 120 is transmitted to the cylinder 132 of the stirling engine connected to the heat conductor 120. Thereby, a temperature difference occurs between one end of the cylinder 132 connected to the heat conductor 120 and the other end of the cylinder 132 not connected to the heat conductor 120. For example, the other end of the cylinder 132, which is not connected to the heat conductor 120, may be in the same condition as the temperature of the outside air or may be lower in temperature due to a gas used as a supplement having a high thermal conductivity, The temperature of the gas at one end connected to the cylinder 132 increases and the piston 134 in the cylinder 132 moves toward the other end of the cylinder 132 due to expansion of the gas. At this time, the temperature of the inside of the cylinder 132 is reduced by the radiating heat radiated to the outside by the radiator 136 disposed outside the cylinder 132, so that the gas in the cylinder 132 contracts and the piston 134 returns again to the cylinder 132 As shown in Fig. When the temperature of the gas in the cylinder 132 rises due to the fermentation heat again and the gas expands, the piston 134 moves to the other end of the cylinder 132. When the temperature decreases, the gas contracts and the piston 134 And may be moved toward the heat conductor 120.

Here, the piston 134 moves from the time when the temperature inside the cylinder 132 due to the fermentation heat is different from the temperature inside the cylinder 132 or the temperature of the outside air, so that the stirling engine can be operated.

In addition, a plurality of stirling engines can be provided, and the fermentation heat generated from the fermentation tank 110 can be supplied at the same time, so that more power can be obtained and more energy can be obtained.

The movement of the repeated piston 134 in this manner allows the stuttering engine to be activated and to acquire energy, which can then be transferred to a generator or battery that can be connected to the stirling engine. For example, electricity can be obtained from a generator or a battery by receiving energy.

In addition, such a system can be installed additionally not only to construct a separate system but also to fuse with the existing waste disposal apparatus and the like, thereby improving the thermal efficiency of the existing apparatus. Therefore, the applicability may be substantially practical.

Accordingly, the energy harvesting system using the fermentation heat according to an embodiment of the present invention can operate the stirling engine using the fermentation heat that is evaporated and discarded during the conventional waste fermentation process, thereby operating the generator with the power generated thereby, Can have an energy cycle. It is also significant in that it is an environmentally friendly power generation system because it can reduce the emission of noise and pollutants by using the Stirling engine and can treat the waste.

Although the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, And various modifications and changes may be made thereto without departing from the scope of the present invention. Accordingly, the spirit of the present invention should not be construed as being limited to the embodiments described, and all of the equivalents or equivalents of the claims, as well as the following claims, belong to the scope of the present invention .

100: Energy Harvesting System
110: Fermentation tank
120: thermoconductor
130: engine
132: Cylinder
134: Piston
136: Radiator

Claims (6)

A fermentation tank having a closed inner space and generating fermentation heat in the inner space;
A heat conductor immersed in the fermenter to transfer fermentation heat; And
An engine having one end connected to the heat conductor and driven by a fermentation heat transferred from the heat conductor;
/ RTI >
Generating a power by moving the piston in the engine by the fermentation heat transferred from the heat conductor,
Wherein the thermoconductor has a protruding end, the protruding end is immersed in the fermenter,
Wherein the thermal conductor is provided in a plurality of thermal conductors arranged radially from the center of the fermenter,
Wherein a portion of the internal space of the fermenter is partitioned and a portion of the internal space of the fermenter is located at an upper portion of the internal space of the fermenter and the remaining portion of the engine and the heat conductor are located at a lower portion of the internal space of the fermenter. Energy Harvesting System using Fermentation Heat. The method according to claim 1,
An energy harvesting system comprising a plurality of heat conductors, wherein the engine is provided in a number corresponding to the number of the heat conductors, and one engine corresponding to each heat conductor is connected. The method according to claim 1,
An energy harvesting system comprising a plurality of heat conductors, wherein the engine is provided in a number smaller than the number of heat conductors, and a plurality of heat conductors can be connected to one engine. The method according to claim 1,
Wherein the engine is a stirling engine, the stirling engine comprises: a cylinder connected to the heat conductor and to which ferroelectric heat is transferred from the heat conductor; a piston disposed inside the cylinder and moved by the fermentation heat; An energy harvesting system using a fermentation heat including a radiator and a supplement for assisting heat dissipation to the outside. The method according to claim 1,
And an energy harvesting system using the fermentation heat that can be connected to the other end of the engine. delete

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