KR101793869B1 - A electric-power generation method use of wastewater and underground water - Google Patents

Abstract

The present invention relates to a power generation method using underground water and wastewater, which comprises: a first step of producing a heat source; a second step of producing an array of electricity and high temperature; a third step of converting the array into a high temperature heat source; a fourth step of distributing, by an incoming power board, electricity generated from a combined heat and power generator and electricity supplied from outside to electricity for a heat pump used in a heat pump or electricity for living; a fifth step of transferring the high temperature heat source converted by the heat exchanger to a building through a first pipe; a sixth step of transferring the high temperature heat source produced from the heat pump to the building through a second pipe; a seventh step of transferring a low temperature heat source produced from the heat pump to the building through a third pipe; an eighth step of storing the high and low temperature heat sources; and a ninth step of transferring the high and low temperature heat sources to the building from a heat source storage part. According to the present invention, the stability on supply of a heat source can be secured even when an adverse condition is generated.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electric power generation method using groundwater and wastewater,

The present invention relates to a power generation method using groundwater and wastewater, and more particularly, to a power generation method using groundwater and wastewater that can reliably provide a stable supply of heat source even in the event of bad conditions, .

A cogeneration facility is an integrated energy facility that simultaneously generates power and heat from a single energy source. Because it produces electricity first and recovers the heat it uses, it has a high energy efficiency of 30-40% than the conventional power generation method. Based on the use of coal and oil, the primary energy consumption is reduced by about 33% to produce the same level of electricity and heat, compared to the case where existing power and heat are supplied independently. The efficiency of such cogeneration depends on how much the array is used. The total efficiency of the cogeneration plant is merely the efficiency of the cogeneration facility for power generation, unless waste heat from the generation facility is utilized at all. Therefore, in the cogeneration system, it is important to maximize the utilization of the array generated from the power generation facility. To this end, an absorption heat pump is introduced. These systems are often referred to as tri-generation in preparation for co-generation. However, there are various ineffective factors in cogeneration due to the heat pump operation, so that it is not easy to efficiently manage various heat sources even though the heat pump is operated. In addition, there is a problem that it is not easy to stably operate the cogeneration power generation system based on the overall heat pump operation even under various bad conditions due to external factors.

Korean Patent No. 10-0776353

An object of the present invention is to provide a power generation method using groundwater and wastewater that can supply a heat source and effectively cope with an impact caused by an external factor, thereby ensuring the stability of the heat source supply even when bad conditions occur.

The present invention relates to a heat pump, comprising: a first stage in which a heat pump is driven by electricity to produce a heat source; A second step of generating electricity and a high temperature arrangement by being driven by the fuel introduced from the cogeneration power plant; A third step of converting the arrangement generated from the cogeneration unit into a high-temperature heat source that can be used for heating and hot water supply of the building; A fourth step of distributing electricity generated from the cogeneration power generator and electricity supplied from the outside to electricity for a heat pump used in a heat pump or electricity for living use; A fifth step of delivering the high-temperature heat source converted from the heat exchanger through the first pipe toward the building; A sixth step of delivering the high-temperature heat source generated from the heat pump to the building through the second pipe; A seventh step of delivering the low temperature heat source produced from the heat pump to the building through the third pipe; An eighth step of storing the high-temperature heat source and the low-temperature heat source transferred from the first pipe to the third heat source storage unit; And a ninth step of transferring the high-temperature heat source and the low-temperature heat source from the heat source storage unit to the building, wherein the heat source storage unit includes a buffer module for buffering an impact applied from outside, Wherein the heat source storage comprises a plurality of assemblies based on a combination of a plurality of storage units having an interior containment space wherein the heat source is stored within the assembly, Wherein the low temperature heat source is stored in a first compartment space inside the assembly or divided into a second compartment space in a second assembly and a third compartment space in a third assembly of the plurality of assemblies, A fifth compartment space within the fifth assembly of the plurality of assemblies, and a fifth compartment space within the fifth assembly of the plurality of assemblies, Wherein the buffer module includes a lower unit in contact with the ground and a buffer unit in contact with the heat source storage unit above the lower unit, A lower fixing plate which is in contact with the lower unit and an elastic housing which is provided between the upper fixing plate and the lower fixing plate, wherein the elastic housing is formed in a zigzag shape on the outer side, Wherein the elastic housing is filled with an elastic filler, the elastic filler is filled to correspond to the shape of the elastic housing, the elastic filler has a plurality of buffer spaces along the longitudinal direction, Wherein the buffer space is formed to have a width equal to or greater than the width of the inner reinforcing plate, The uppermost reinforcing plate facing the upper fixing plate is formed with a bottom protrusion of a predetermined shape on the lower surface of the inner reinforcing plates, and the lower most reinforcing plate facing the lower fixing plate among the inner reinforcing plates has a predetermined shape Wherein the upper reinforcing plate and the lower reinforcing plate are formed with protrusions on the upper surface and the lower surface, respectively, and the upper reinforcing plate and the lower reinforcing plate are formed on the upper fixing plate and the lower fixing plate, A first pressing force measuring sensor for measuring a first pressing force is provided in a plurality of spaced apart from each other and a second pressing force for measuring a second pressing force generated between the lower fixing plate and the lower unit is formed on the lower fixing plate, The present invention provides a method of generating electricity using groundwater and wastewater, the measurement sensors being spaced apart from each other.

The power generation method using ground water and wastewater according to the present invention has the following effects.

First, it is possible to provide a power generation method using ground water and wastewater that can efficiently manage various heat sources by eliminating various ineffective factors on the cogeneration power generation through heat pump operation.

Secondly, it is possible to provide a power generation method using groundwater and wastewater, which can be operated stably over a wide range of difficult conditions due to external factors.

1 is a view showing a power generation system using a heat pump according to an embodiment of the present invention.
2 to 3 are views showing a heat source storage unit among the configurations according to FIG.
FIG. 4 is a view showing an embodiment of a buffering unit among the arrangements according to FIG. 1. FIG.
FIG. 5 is a view showing another embodiment of the shock absorber among the configurations according to FIG. 1. FIG.
FIG. 6 is a view showing another embodiment of the uppermost stiffener, the suspended stiffener, and the lowermost stiffener of the structures according to FIGS.
FIG. 7 is a view showing another embodiment of the shock absorber among the configurations according to FIG. 1. FIG.
8 is a diagram illustrating a power generation method according to an embodiment of the present invention.
9 to 11 are views schematically showing a part of the configurations of a power generation system according to another embodiment of the present invention.
12 is a diagram illustrating a power generation method according to another embodiment of the present invention.

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

1 is a view illustrating a power generation system using a heat pump according to an embodiment of the present invention. 2 to 3 are views showing a heat source storage unit among the configurations according to FIG. FIG. 4 is a view showing a part of the configurations of the heat source storage unit according to FIG. 1. FIG.

1 to 4, a power generation system 10 using a heat pump includes a water column 11, a cogeneration system 12, a heat exchanger 13, a heat pump 16, a pipe, a heat source storage 18 ). The piping includes a first pipe 14, a second pipe 15 and a third pipe 17, and the heat source storage unit 18 includes a buffer module 181.

The heat pump 16 is driven by electricity and produces a high-temperature heat source or a low-temperature heat source. The heat pump 16 repeats the reverse car- nocycle to produce a high-temperature heat source used for heating and hot water supply of the building, and produces a low-temperature heat source used for cooling the building.

The heat pump 16 recovers a high temperature heat source and a low temperature heat source from air heat, waste heat, stream heat, ground water heat, underground heat, waste heat and seawater heat, generates heat three times or more of the electric power consumption, Heat source is produced.

The cogeneration unit includes a generator for generating electricity from primary energy such as petroleum, coal, and natural gas, an engine for driving the generator, and an arrangement recovery unit for recovering heat generated in the engine. The arrangement of the cogeneration system 12 has a temperature of 400 to 650 degrees Celsius.

The water column 11 appropriately distributes the electricity generated from the cogeneration system 12 and the electric power supplied from the electric power source and supplies the electricity to the heat pump 16 for operating the heat pump 16, It can be used as electricity for life.

For example, in the season when cooling or heating is frequent, the water generator 11 supplies the electric power generated from the cogeneration / generator 12 to the heat pump 16 to perform peak control for reducing power consumption supplied from the electric power source Can be performed.

In addition, since the water generator 11 supplies the electricity generated by the cogeneration unit 12 to the building in a season when the cooling and heating is not required, the power consumption supplied from the power supply source can be further reduced. Furthermore, it is also possible to create value added by back-feeding the produced power source.

The first pipe 14 is connected to the heat exchanger 13 and supplies a high-temperature heat source supplied through the heat exchanger 30 to the building. The high-temperature heat source is delivered to the heating piping installed on the floor of the building to perform heating. In particular, the high-temperature heat source is supplied to the heat source storage unit 18 through the first piping 14 to be supplied to the building.

The second pipe 15 is connected to the heat pump 16 and supplies a high temperature heat source supplied through the heat pump 16 to the building to be used for heating and hot water production . Similarly, the high-temperature heat source supplied through the second pipe 15 is supplied to the heat source storage unit 18 and then supplied to the building.

The third pipe 17 is connected to the heat pump 16 and supplies a low-temperature heat source supplied through the heat pump 16 to the building. Similarly, the high-temperature heat source supplied through the third pipe 17 is supplied to the heat source storage unit 18 and then supplied to the building.

The high-temperature heat source generated due to the operation of the heat pump 16 is used together with the arrangement generated in the cogeneration unit 12 to generate the heating and hot water of the building, thereby minimizing the heating cost. Further, the low-temperature heat source generated by the operation of the heat pump 16 is used for cooling the building, so that the amount of electricity supplied from the power source can be minimized.

The heat generated from the cogeneration unit 12 is mainly used as an energy source for operating the heat pump 16 and the heat generated by the heat exchanger 13 connected to the cogeneration unit 12, The high temperature heat source generated in the heat pump 16 is used for heating and hot water production of the building and the low temperature heat source generated from the heat pump 16 can be used for cooling the building.

2 to 3, the heat source storage unit 18 stores heat sources supplied from the first pipe 14 to the third pipe 17, and includes a plurality of storage units (The first storage unit UN1, the second storage unit UN2, the third storage unit UN3, the fourth storage unit UN4, the Nth storage unit UNN, etc.) (E.g., polygonal, circular, oval, etc.).

In an embodiment of the present invention, it is assumed that the overall shape of the heat source storage unit 18 is a cube. The heat source storage unit 18 includes a plurality of assemblies A1, A2, A3, and A4 based on a combination of a plurality of storage units UN1, UN2, UN3, and UN4 having an internal accommodating space, (A1, A2, A3, A4).

The storage units UN1, UN2, UN3, and UN4 correspond to individual blocks, and the blocks are arranged in an M x N array when viewed from the front, and are arranged in an O X P array when viewed from the top. 2, the storage units UN1, UN2, UN3, and UN4, as shown in FIG. 2, for example, have the same structure, They are arranged in four rows, each row consisting of three layers. The leftmost upper end corresponds to the first assembly A on the basis of this state and corresponds to the second assembly B, the third assembly C and the fourth assembly D sequentially. Although only the fourth assembly D is shown in the drawing, it can be assumed that the fifth to Nth assemblies are provided.

The high-temperature heat source supplied from the pipe may be stored in a first compartment space, which is a storage space inside the first assembly (A), or a second compartment space, which is a storage space inside the second assembly (B) And the third compartment space which is a storage space of the third assembly (C).

The low-temperature heat source may be stored in the fourth compartment space of the fourth assembly D among the plurality of assemblies, or may be stored in the fifth compartment space of the fifth assembly (not shown) In the sixth partition space inside the first partition space.

However, it is to be understood that the storage locations of the high-temperature heat source and the low-temperature heat source can be selectively stored as needed.

Meanwhile, the first storage units UN1 of the first assembly A1 are provided with a first display unit DP1 in the form of an output window for outputting status information to the outward facing surfaces thereof, The second storage units UN2 of the third assembly A3 are each provided with a second display unit DP2 for outputting status information to the outwardly facing surfaces thereof and the third storage units UN3 of the third assembly A3 And a fourth display unit (DP4) for outputting status information to the respective outwardly facing surfaces. The fourth assembly (A4) fourth storage units (UN4) 4 display unit DP4. The state information may include temperature information for a heat source stored in the heat source, filling prediction time information predicted to be fillable by a heat source, remaining amount information, exhaustion prediction time information predicted to be exhausted, The display unit includes time output information for outputting a color for mutual identification. That is, the visual output information can be outputted in different colors for distinguishing between the first assembly A1 to the fourth assembly A4 or the like. Each of the storage units A1, < RTI ID = 0.0 > A, < / RTI >

The buffer module 181 includes a lower unit 1812 in contact with the ground and a buffer unit 1811 in contact with the heat source storage unit 18 above the lower unit 1812. The buffer unit 1811 includes an upper fixing plate 1811a and a lower fixing plate 1811b that are in contact with the lower surface of the heat source storage unit 18 and a lower fixing plate 1811b that faces the lower unit 1812. The upper fixing plate 1811a, And elastic housings 1811c and 1811d provided between the lower fixing plates 1811b. At this time, the outer side portions of the elastic housings 1811c and 1811d are formed in a zigzag shape.

The elastic members 1811e and 1811d are filled with elastic fillers 1811e so that the elastic fillers 1811e correspond to the shapes of the elastic housings 1811c and 1811d and the elastic fillers 1811e A plurality of predetermined buffer spaces H1 are formed along the longitudinal direction, and internal reinforcing plates are provided between the respective buffer spaces H1.

At this time, it is preferable that the buffer space H1 is formed to have a width equal to or larger than the width of the inner reinforcing plate. The uppermost reinforcing plate 1811f facing the upper fixing plate 1811a among the inner reinforcing plates has a bottom protrusion T1 of a predetermined shape on the lower surface thereof.

The uppermost reinforcing plate 1811g facing the lower fixing plate 1811b of the inner reinforcing plates has a predetermined upper protrusion T2 formed on the upper surface thereof and the uppermost reinforcing plate 1811f and the lowest reinforcing plate 1811b 1811g are formed with upper surface protrusions T2 and lower surface protrusions T1 on the upper and lower surfaces, respectively.

Each of the uppermost reinforcing plate 1811f, the intermediate reinforcing plate 1811h and the lowermost reinforcing plate 1811g is formed so that the upper protrusion T2 and the lower protrusion T1 And are brought into mutual contact via the buffer space H1. Here, the upper surface protruding portion T2 and the lower surface protruding portion T1 may be formed as concave and convex shapes that are mutually combined.

FIG. 5 is a view showing another embodiment of the shock absorber 1811 among the configurations according to FIG. 5, the upper fixing plate 1811a includes a first fixing plate 1811a1 disposed above and facing the bottom surface of the heat source storage unit 18, and a second fixing plate 1811b1 disposed below the first fixing plate 1811a1 to be slidable in the horizontal direction. And a second fixing plate 1811a2 which is in contact with the elastic housing 1811c and 1811d and the uppermost reinforcing plate 1811b1.

The lower fixing plate 1811b includes a third fixing plate 1811b1 which is in contact with the lower unit 1812 and a third fixing plate 1811b1 which is coupled to the upper portion of the third fixing plate 1811b1 so as to be slidable in the horizontal direction, 1811c, and 1811d, and a fourth fixing plate 1811b2 that is in contact with the lowermost reinforcing plate 1811g.

A predetermined hollow region H2 is formed at the central portion of the elastic filler 1811e and a buffer 1811i for buffering the heat source storage portion 18 is formed on the hollow region H2, .

The buffer 1811i includes an upper plate 1811i1 and a lower plate 1811i2 which are mutually coupled via elastic means and the upper plate 1811i1 and the lower plate 1811i2 are connected to the upper fixing plate 1811a and the lower And is bound to the fixing plate 1811b so as to be slidable in the horizontal plane.

FIG. 6 is a view showing another embodiment of the uppermost stiffener 1811f, the plurality of suspended stiffeners 1811h, and the lowermost stiffener 1811g among the structures according to FIG. 4 or FIG.

6, the uppermost stiffening plate 1811f includes an uppermost upper plate 1811f1 contacting the upper fixing plate 1811a and an uppermost lower plate 1811f2 bounded by the uppermost plate and the elastic body E2 do. Here, a bottom projection portion T1 is formed on the bottom surface of the uppermost lower plate 1811f2.

The suspended reinforcing plate 1811h includes an intermediate upper plate 1811h1 facing the uppermost lower plate 1811f with the buffer space H1 interposed therebetween and a lower bottom plate 1811h1 connected to the intermediate upper plate 1811h1 via an elastic body 1811h2). An upper surface protrusion T2 is formed on the upper surface of the intermediate top plate 1811h1.

The lowermost reinforcing plate 1811g includes a lowermost upper plate 1811g1 opposed to the lower plate 1811h2 with the buffer space interposed therebetween and a lowermost lower plate 1811g2 connected to the lowestermost plate 1811g1 via an elastic body . An upper surface protrusion T2 is formed on the upper surface of the lowermost top plate 1811g1.

FIG. 7 is a view showing another embodiment of the shock absorber 1811 among the configurations according to FIG. Hereinafter, the description will be focused on the technical features. Referring to Figure 7,

The second fixing plate 1811a2 extends at least outward beyond the area of the first fixing plate 1811a1 and has upper protrusions UT (not shown) extending upward at both ends of both sides of the second fixing plate 1811a2, Is formed.

The fourth fixing plate 1811b2 extends at least outward beyond the area of the third fixing plate 1811b1 and has a downward protruding portion DT extending upwardly from both ends of both sides of the fourth fixing plate 1811b2 Is formed.

At least a part of the upper projecting portion UT is positioned so as to face the first fixing plate 1811a1. The upper projecting portion UT and the first fixing plate 1811a1 are coupled to each other by an elastic means E5, Restoring force is given.

At least a part of the downward projecting portion DT is positioned to face the fourth fixing plate 1811b2 so that the lower protruding portion DT and the fourth fixing plate 1811b2 are bound to each other by the elastic means E6, .

On the other hand, the buffer unit 1811 has been described on the assumption that the overall shape is a rectangular parallelepiped or a cuboid. That is, the upper fixing plate 1811a, the lower fixing plate 1811b, and the elastic housing 1811c are formed of a rectangular parallelepiped or a hexahedron.

Here, the elastic housing 1811c is formed in a zigzag shape as described above, so that it is possible to smoothly bend the upper and lower portions more smoothly against external shocks. The shock absorber 1811i also allows the shock absorber 1811c to be more easily buffered in response to an external impact with the elastic housing 1811c. The uppermost reinforcing plate 1811f, the lowermost reinforcing plate 1811g and the intermediate reinforcing plate 1811h are also connected to the elastic filler 1811e via the buffer space H1, Contact in a buffered manner. At this time, the uppermost reinforcing plate 1811f, the lowermost reinforcing plate 1811g, and the intermediate reinforcing plate 1811h serve to suppress the flow in the horizontal direction through the upper surface protruding portion T2 and the lower surface protruding portion T1, Thereby preventing the flow caused by the impact. That is, although not shown in the drawing, when the shock absorber 1811 is compared with the shock absorber before and after the impact, the shape after the impact is exerted is constantly pressed between the upper and lower sides.

8 is a view showing a power generation method using the heat pump 16 according to an embodiment of the present invention. Hereinafter, the contents overlapping with those described above will be omitted.

Referring to FIG. 8, in the first power generation method using the heat pump 16, the heat pump 16 is driven by electricity to produce a heat source in a first step S110.

Next, in the second step S120, the fuel is introduced into the cogeneration system 12 to produce electricity and a high temperature arrangement.

Next, in a third step S130, the heat exchanger 13 converts the arrangement generated from the cogeneration unit 12 into a high-temperature heat source which can be used for heating and hot water supply of the building.

Next, in the fourth step S140, the water generator 11 supplies electricity generated from the cogeneration unit 12 and electricity supplied from the outside (power supply source) to the heat pump 16 used in the heat pump 16 Distribute it to electricity or live electricity.

Next, the high-temperature heat source converted from the heat exchanger 13 is transmitted to the building through the first pipe 14 in the fifth step S150.

Next, in a sixth step (S160), the high-temperature heat source produced from the heat pump (16) is transmitted to the building through the second pipe (15).

Next, in a seventh step (S170), the low-temperature heat source produced from the heat pump 16 is transmitted to the building through the third pipe 17.

The high temperature heat source and the low temperature heat source transferred from the first pipe 14 to the third pipe 17 are stored in the heat source storage unit 18 in an eighth step S180.

Finally, in the ninth step S190, the high-temperature heat source and the low-temperature heat source are transmitted from the heat source storage unit 18 to the building.

9 to 10 are views schematically showing a part of the configurations of a power generation system according to another embodiment of the present invention. Hereinafter, the description will be focused on the technical features.

9 to 10 are views schematically showing a part of the configurations of a power generation system according to another embodiment of the present invention. Hereinafter, the description will be focused on the technical features.

9 to 10, the power generation system includes a heat pump 16 for producing a high-temperature heat source or a low-temperature heat source including operation of groundwater and wastewater; A cogeneration unit (12) for producing electricity and producing a high temperature arrangement; A heat exchanger 13 for converting the arrangement generated from the cogeneration system 12 into a high temperature heat source; A water column 11 for distributing the supplied electricity to the electric power for the heat pump 16 used in the heat pump 16 or the electric power for domestic use; A first pipe 14 for transferring the high temperature heat source converted from the heat exchanger 13 to the building, a second pipe 15 for supplying the high temperature heat source produced from the heat pump 16 to the building, A pipe including a third pipe (17) for supplying a low-temperature heat source produced from the pump (16) to the building; And a heat source storage unit 18 for storing a heat source supplied through the pipe. The heat source storage unit 18 includes a buffer module 181 for buffering an impact applied from the outside to the heat source storage unit 18 and the heat source storage unit 18 includes a plurality of storage units Wherein the heat source is stored within the assembly.

The high temperature heat source may be stored in a first compartment space in the first assembly A of the plurality of assemblies or may be stored in a second compartment space in the second assembly B of the plurality of assemblies, ), And the low-temperature heat source is stored in the fourth compartment space of the fourth assembly (D) among the plurality of assemblies, or the fifth compartment of the plurality of assemblies And the sixth compartment space inside the sixth assembly. The buffer module 181 includes a lower unit in contact with the ground and a buffer unit 1811 in contact with the heat source storage unit 18 above the lower unit. A lower fixing plate 1811b facing the lower unit and an elastic housing 1811c provided between the upper fixing plate 1811a and the lower fixing plate 1811b, 1811d, and the outer side portions of the elastic housings 1811c and 1811d are formed in a zigzag shape.

The elastic members 1811c and 1811d are filled with elastic fillers 1811e so that the elastic fillers 1811e are filled to correspond to the shapes of the elastic housings 1811c and 1811d, A plurality of cushioning spaces H1 are formed in the cushioning space H1 and an inner reinforcing plate is provided between the cushioning spaces H1. The cushioning space H1 is formed to have a width greater than the width of the inner reinforcing plate, The uppermost reinforcing plate facing the upper fixing plate 1811a of the inner reinforcing plates is formed with a bottom protrusion T1 having a predetermined shape on the lower surface of the upper reinforcing plate 1811a, The reinforcing plate has a top surface protruding portion T2 of a predetermined shape on its upper surface and a recessed reinforcing plate 1811h positioned between the uppermost reinforcing plate and the lowermost reinforcing plate has protrusions T3 . A plurality of first pressing force measuring sensors S1 for measuring a first pressing force generated between the upper fixing plate 1811a and the heat source storing unit 18 are provided on the upper fixing plate 1811a, And a second pressing force measuring sensor S2 for measuring a second pressing force generated between the lower fixing plate 1811b and the lower unit are spaced apart from each other on the lower fixing plate 1811b.

A second cushioning space H3 is formed on the elastic filling material 1811e positioned between the buffer spaces H1 and a supporting unit 1811b having a predetermined shape is provided between the upper fixing plate 1811a and the lower fixing plate 1811b. (191). Each of the suspended reinforcing plates 1811h is disposed on the supporting unit 191 while being positioned on the second cushioning space H3 so as to be rotatable and on the supporting unit 191, . Each of the intermittent reinforcing plates 1811h is operated in conjunction with the driving means 190. [ Each of the interrupted reinforcing plates 1811h is provided so as to be able to flow to one side and the other side in the longitudinal direction on the second cushioning space H3 through the driving means 190. [ Further comprising a control unit for controlling the operation of the buffer unit 1811. The control unit controls the operation of the break gusset 1811h based on the measured first pressing force and the second pressing force , When the first pressing force and the second pressing force exceed a predetermined value, the respective intermittent reinforcing plates 1811h are rotated at a high speed, and when the first pressing force and the second pressing force are below a predetermined value, .

The driving unit 190 is provided to be able to move up and down within a certain range on the supporting unit 191 and the control unit adjusts the height of the intermittent reinforcing plate 1811h through the driving unit 190, When the first pressing force exceeds a predetermined value, the driving means (190) of the upper part of the driving means (190) is made to flow upward, and when the second pressing force exceeds the predetermined value , And a part of the driving means (190) below the driving means (190) is caused to flow downward.

More specifically, the driving unit 190 includes a driving unit 191 mounted on the supporting unit 191 to generate torque and capable of moving up and down on the supporting unit 191, 1811h, and a piston 194. The cylinder 193 and the piston 194 cooperate with each other. The intermittent reinforcing plate 1811h can flow vertically and horizontally based on the flow of the driving unit 191 or the flow of the cylinder 193 and the piston 194.

12 is a diagram showing a power generation method using a heat pump 16 according to an embodiment of the present invention. Hereinafter, the contents overlapping with those described above will be omitted.

Referring to FIG. 12, in the first method (S210), the heat pump 16 is driven by electricity to produce a heat source.

Next, in the second step S220, it is driven by the fuel introduced from the cogenerator 12 to produce electricity and a high temperature arrangement.

Next, in a third step S230, the heat exchanger 13 converts the arrangement generated from the cogeneration unit 12 into a high-temperature heat source that can be used for heating and hot water supply of the building.

Next, in the fourth step S240, the water generator 11 supplies electricity generated from the cogeneration unit 12 and electricity supplied from the outside (power supply source) to the heat pump 16 used in the heat pump 16 Distribute it to electricity or live electricity.

Next, the high-temperature heat source converted from the heat exchanger 13 is transmitted to the building through the first pipe 14 in the fifth step (S250).

Next, in a sixth step (S260), the high-temperature heat source produced from the heat pump (16) is transmitted to the building through the second pipe (15).

Next, in a seventh step (S270), the low-temperature heat source produced from the heat pump 16 is transmitted to the building through the third pipe 17.

Next, a high-temperature heat source and a low-temperature heat source transferred from the first pipe 14 to the third pipe 17 are stored in the heat source storage unit 18 in an eighth step S280.

Finally, in the ninth step S290, the high-temperature heat source and the low-temperature heat source are transferred from the heat source storage unit 18 to the building.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

10: Power generation system 11:
12: Cogeneration generator 13: Heat exchanger
14: first pipe 15: second pipe
16: Heat pump 17: Third piping
18: Heat source storage unit UN1: First storage unit
UN2: second storage unit UN3: third storage unit
A: first assembly B: second assembly
C: Third assembly D: Fourth assembly
181: buffer module 1811: buffer unit
1811a: upper fixing plate 1811a1: first fixing plate
1811a2: second fixing plate 1811b: lower fixing plate
1811b1: third fixing plate 1811b2: fourth fixing plate
1811c, 1811d: elastic housing 1811e: elastic filler
1811f: uppermost stiffening plate 1811f1: uppermost stiffening plate
1811f2: uppermost lower plate E2: elastic body
1811g: Lowermost reinforced plate 1811g1: Lowermost plate
1811g2: lowest bottom plate E4: elastomer
1811h: Interrupted reinforcement plate 1811h1: Interrupted upper plate
1811h2: lower plate E3: elastomer
1811i: buffer 1811i1: top plate
1811i2: Lower plate E: Elastic means
T1: lower protrusion T2: upper surface protrusion
H1: buffer space H2: hollow region
1812: Lower unit

Claims (11)

A first step in which the heat pump is driven by electricity to produce a heat source; A second step of generating electricity and a high temperature arrangement by being driven by the fuel introduced from the cogeneration power plant; A third step of converting the arrangement generated from the cogeneration unit into a high-temperature heat source that can be used for heating and hot water supply of the building; A fourth step of distributing electricity generated from the cogeneration power generator and electricity supplied from the outside to electricity for a heat pump used in a heat pump or electricity for living use; A fifth step of delivering the high-temperature heat source converted from the heat exchanger through the first pipe toward the building; A sixth step of delivering the high-temperature heat source generated from the heat pump to the building through the second pipe; A seventh step of delivering the low temperature heat source produced from the heat pump to the building through the third pipe; An eighth step of storing the high-temperature heat source and the low-temperature heat source transferred from the first pipe to the third heat source storage unit; And a ninth step of transferring the high-temperature heat source and the low-temperature heat source from the heat source storage unit to the building, wherein the heat source storage unit includes a buffer module for buffering an impact applied from outside, As a result,
Wherein the heat source storage unit includes a plurality of assemblies based on a combination of a plurality of storage units having an inner storage space, the heat source is stored inside the assembly,
The high temperature heat source may be stored in a first compartment space in the first assembly of the plurality of assemblies or may be divided into a second compartment space in the second assembly and a third compartment space in the third assembly of the plurality of assemblies Stored,
Wherein the low temperature heat source is stored in a fourth compartment space in the fourth assembly of the plurality of assemblies or divided into a fifth compartment space in the fifth assembly and a sixth compartment space in the sixth assembly out of the plurality of assemblies, Then,
The buffer module includes:
A lower unit in contact with the ground, and a buffer unit contacting the heat source storage unit above the lower unit,
The shock absorber includes an upper fixed plate facing the bottom of the heat source storage unit, a lower fixed plate facing the lower unit, and an elastic housing provided between the upper fixed plate and the lower fixed plate. The elastic housing has an outer side surface And is formed in a zigzag shape,
Wherein the elastic housing is filled with an elastic filler, the elastic filler is filled to correspond to the shape of the elastic housing, a plurality of buffer spaces are formed along the longitudinal direction of the elastic filler,
Wherein an inner reinforcing plate is provided between each of the buffer spaces, and the buffer space is formed to have a width equal to or greater than a width of the inner reinforcing plate,
The uppermost reinforcing plate facing the upper fixing plate is formed with a bottom protrusion of a predetermined shape on the lower surface of the inner reinforcing plates, and the lower most reinforcing plate facing the lower fixing plate among the inner reinforcing plates has a predetermined shape Wherein the upper reinforcing plate and the lower reinforcing plate are formed with protrusions on upper and lower surfaces, respectively,
A first pressing force measuring sensor for measuring a first pressing force generated between the upper fixing plate and the lower unit is provided on the upper fixing plate so as to be spaced apart from each other and on the lower fixing plate, And the second pressurizing force measuring sensor for measuring the second pressurizing force generated by the second pressurizing force measuring sensor are spaced apart from each other. The method according to claim 1,
A second buffer space is formed on the elastic filler located between the buffer spaces,
A supporting unit having a predetermined shape is provided between the upper fixing plate and the lower fixing plate,
Each of the interrupted reinforcing plates
A second buffer space disposed on the second buffer space and coupled to the support unit,
A plurality of driving means are provided on the supporting unit,
Wherein each of the interrupted reinforcing plates uses groundwater and wastewater operated in conjunction with the driving means. The method of claim 2,
Each of the interrupted reinforcing plates
And the groundwater and the wastewater are provided so as to flow to one side and the other side in the longitudinal direction on the second cushion space through the driving means. The method of claim 3,
And a control unit for controlling the operation of the shock absorber unit,
Wherein the control unit controls the operation of the suspended reinforcing plate based on the measured first pressing force and the second pressing force,
Wherein when each of the first pressing force and the second pressing force exceeds a predetermined value, each of the intermittent reinforcing plates is rotated at a high speed,
And the groundwater and the wastewater are used to rotate the suspended gusset plate at a low speed when the measured value is less than the predetermined value. The method of claim 4,
Wherein the driving means is provided to be able to ascend and descend in a certain range on the support unit,
Wherein,
The height of the intermittent reinforcing plate is adjusted through the driving means,
Wherein when the first pressing force exceeds a predetermined value, the driving means of the upper portion of the driving means is caused to flow upward,
And the groundwater and the wastewater are used so that the driving means of the lower one of the driving means is caused to flow downward when the second pressing force exceeds the predetermined value. The method according to claim 1,
Wherein each of the uppermost stiffening plate and the lowermost stiffening plate includes:
Wherein the upper surface protruding portion and the lower surface protruding portion are brought into contact with the intermittent reinforcing plate via the buffer space when vibration based on an external impact is generated. The method of claim 6,
Wherein the upper surface protrusion and the lower surface protrusion of the uppermost stiffening plate and the lowermost stiffening plate use groundwater and wastewater formed in a concavo-convex shape corresponding to the protrusions of the intermittent reinforcing plate. The method of claim 7,
The upper fixing plate,
A first fixing plate disposed above the bottom surface of the heat source storage portion,
And a second fixing plate coupled to a lower portion of the first fixing plate so as to be slidable in a horizontal direction and in contact with the elastic housing and the uppermost reinforcing plate. The method of claim 8,
The lower fixing plate,
A lower third fixing plate contacting the lower unit,
And a fourth fixing plate coupled to an upper portion of the third fixing plate so as to be slidable in a horizontal direction and in contact with the elastic housing and the lowermost reinforcing plate. delete delete

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