JP6954019B2 - Cogeneration system - Google Patents

Description

The present invention relates to a cogeneration system.

As a type of cogeneration system (fuel cell system), those shown in Patent Documents 1 and 2 are known. The cogeneration system of Patent Document 1 includes an opening / closing door that can be opened / closed on one side surface arranged on the side of the housing. The opening / closing door is opened to maintain the components such as the power generation module. Further, in the cogeneration system of Patent Document 2, maintenance of components is performed from a specific aspect of the housing.

Japanese Unexamined Patent Publication No. 2011-228180 Japanese Unexamined Patent Publication No. 2014-137845

However, when the cogeneration system is installed in a relatively narrow place such as an urban area, it is not possible to secure a space for opening the opening / closing door as in Patent Document 1, or it stands in front of a specific surface as in Patent Document 2. It is possible that the space required for maintenance cannot be secured.

Therefore, the present invention has been made to solve the above-mentioned problems, and an object of the present invention is to provide a cogeneration system capable of performing maintenance of a power generation module even when it is installed in a relatively narrow place. do.

In order to solve the above problems, the cogeneration system according to claim 1 is a cogeneration system including a rectangular housing containing a power generation module having a lower surface, and the housing includes a plurality of frames. It is a frame body formed by connecting, and is arranged so as to cover each side surface of the frame body having a rectangular storage portion for accommodating the power generation module and the side surface of the storage portion, and is detachably attached. A support portion having a support surface for supporting the power generation module at a supported portion provided on the lower side surface of the power generation module as well as a storage portion provided at the bottom of the storage portion. It is provided on one side of the storage unit in the lateral direction and the longitudinal direction in the top view of the storage unit, and by moving the power generation module along the lateral direction, the inside of the storage unit and the outside of the housing can be connected. The first open portion that is movably open between the two, and the storage portion that is provided on the side of the other side in the lateral direction and the longitudinal direction in the top view of the storage portion, and moves the power generation module along the longitudinal direction. A second open portion is provided so as to be movable between the storage portion and the outside of the housing.

According to this, the power generation module housed in the rectangular parallelepiped storage part is provided on one side in the lateral direction and the longitudinal direction in the top view of the storage part in the storage part after the panel is removed. It can be taken out to the outside through one open portion or a second open portion provided on the side in the other direction in the lateral direction and the longitudinal direction in the top view of the storage portion in the storage portion. Even if the space for installing the cogeneration system does not allow enough space to take out the power generation module from one side of the storage unit, it can be used as a carry-in route for the cogeneration system on the other side of the storage unit. There is a space that has been created. Therefore, in this case, the power generation module can be taken out from the side of the storage portion in the other direction. Therefore, maintenance of the power generation module can be performed even when the cogeneration is installed in a relatively narrow place.

It is a perspective view which shows the appearance of one Embodiment of the cogeneration system which concerns on this invention. It is a schematic diagram of the cogeneration system shown in FIG. It is a cross-sectional view of the power generation unit shown in FIG. It is a bottom view of the power generation unit shown in FIG. FIG. 3 is a perspective view showing a state in which the front side panel and the left side panel are removed in the cogeneration system shown in FIG. It is a perspective view of the frame body shown in FIG. It is a top view of the frame body and the power generation unit shown in FIG. It is sectional drawing of the frame body and the power generation unit along the line VIII-VIII shown in FIG. It is sectional drawing of the frame body and the power generation unit along the IX-IX line shown in FIG. It is sectional drawing of the frame body and the power generation unit along the X-ray shown in FIG. 7. It is a top view of the frame body and the power generation unit shown in FIG. 5, and shows a state in which the power generation unit is slid forward. It is a top view of the frame body and the power generation unit shown in FIG. 11, and shows a state in which the power generation unit is further slid forward from the state shown in FIG. It is a top view of the frame body and the power generation unit shown in FIG. 5, and shows a state in which the power generation unit is further slid to the left from the state shown in FIG.

Hereinafter, an embodiment of the cogeneration system according to the present invention will be described with reference to the drawings. In this specification, for convenience of explanation, the upper side and the lower side in FIG. 1 are the upper side and the lower side of the cogeneration system 1, respectively, and the lower left side and the upper right side are the front side and the rear side of the cogeneration system 1, respectively, and the upper left side is also the same. The side and the lower right side will be described as the right side and the left side of the cogeneration system 1, respectively.

The cogeneration system 1 is a fuel cell system in this embodiment. As shown in FIG. 1, the cogeneration system 1 includes a rectangular parallelepiped housing 10. In the present embodiment, the lateral direction and the front-rear direction in the top view of the housing 10 coincide with each other, and the longitudinal direction and the left-right direction in the top view of the housing 10 coincide with each other.

As shown in FIG. 2, the cogeneration system 1 includes a power generation module 11 (30), a heat exchanger 12, a power conversion device 13, a water tank 14, a control device 15, and a hot water storage tank 16. The power generation module 11, the heat exchanger 12, the power conversion device 13, the water tank 14, the control device 15, and the hot water storage tank 16 are housed in the housing 10.

The power generation module 11 includes at least a fuel cell 34, which will be described later. The power generation module 11 is formed in a rectangular parallelepiped box shape having a lower side surface 31a (see FIGS. 2 and 3). The power generation module 11 is arranged in a rectangular parallelepiped storage portion 70 (see FIGS. 2 and 5).

In a state where the power generation module 11 is housed in the storage unit 70, each side surface of the power generation module 11 faces each side surface of the storage unit 70. The lateral direction of the storage unit 70 in the top view (corresponding to one direction of the present invention in the present embodiment) coincides with the lateral direction of the power generation module 11 in the top view, and the lateral direction of the housing 10, that is, Matches in the front-back direction. Further, the longitudinal direction of the storage unit 70 in the top view (corresponding to the other direction of the present invention in the present embodiment) coincides with the longitudinal direction of the power generation module 11 in the top view, and the longitudinal direction of the housing 10, that is, left and right. Match the direction. Therefore, each side surface of the storage portion 70 faces each side surface of the housing 10. The storage portion 70 is provided on the upper side in the housing 10. Details of the storage unit 70 will be described later.

The power generation module 11 is supplied with a reforming raw material and an oxidant gas necessary for power generation of the fuel cell 34. The reforming raw material is used in the fuel cell 34 as a reforming fuel reformed using reformed water. The oxidant gas is air (cathode air).

In the power generation module 11, reforming raw materials are supplied from the supply source Gs via the fuel supply pipe 11a by driving the fuel pump 11a1. In the power generation module 11, reformed water is supplied from the water tank 14 via the reformed water supply path 11b by driving the reformed water pump 11b1. Further, in the power generation module 11, the air in the housing 10 is supplied by driving the cathode air blower 11c1 via the cathode air supply path 11c.

The heat exchanger 12 is a heat exchanger in which combustion exhaust gas (described later) exhausted from the power generation module 11 is supplied, hot water is supplied from the hot water storage tank 16, and the combustion exhaust gas and hot water are exchanged for heat. .. An exhaust pipe 11d from the power generation module 11 is connected (penetrated) to the heat exchanger 12. The heat exchanger 12 is connected to the condensed water supply pipe 12a connected to the water tank 14.

The hot water storage tank 16 stores hot water, and a hot water storage water circulation line 17 through which the hot water is circulated (circulated in the direction of the arrow in the figure) is connected. On the hot water storage water circulation line 17, the hot water storage water circulation pump 17a and the heat exchanger 12 are arranged in order from the lower end to the upper end.

In the heat exchanger 12, the combustion exhaust gas from the power generation module 11 is introduced into the heat exchanger 12 through the exhaust pipe 11d, and heat is exchanged with the hot water to be cooled and in the combustion exhaust gas. The water vapor contained in is condensed. The flue gas after cooling is discharged to the outside through the exhaust pipe 11d. Further, the condensed condensed water is supplied to the water tank 14 through the condensed water supply pipe 12a. The water tank 14 uses an ion exchange resin to purify the condensed water.

The waste heat recovery system 18 is configured from the heat exchanger 12, the hot water storage tank 16, and the hot water storage water circulation line 17 described above. The waste heat recovery system 18 collects and stores the waste heat of the power generation module 11 in the hot water storage water.

Further, the power conversion device 13 inputs a DC voltage output from the fuel cell 34, converts it into a predetermined AC voltage, and is connected to an AC system power supply 20a and an external power load 20c (for example, an electric appliance). Output to line 20b. Further, the power conversion device 13 inputs the AC voltage from the system power supply 20a via the power supply line 20b, converts it into a predetermined DC voltage, and outputs it to the auxiliary machine or the control device 15.

The control device 15 controls at least the power generation module 11. The control device 15 drives an auxiliary machine to control the operation of the cogeneration system 1. The control device 15 controls the generated power of the fuel cell 34 so as to consume the external power load 20c during the power generation operation of the cogeneration system 1 (load follow-up operation). The fuel supply pipe 11a, the reformed water supply line 11b, the cathode air supply line 11c, the exhaust pipe 11d, and the power supply line 20b described above are detachably provided with respect to the power generation module 11.

As shown in FIG. 3, the power generation module 30 includes a casing 31, an evaporation unit 32, a reforming unit 33, a fuel cell 34, a combustion unit 35, a heat insulating member 36, and a supported unit 40. The casing 31 has a lower side surface 31a and is provided in a box shape by a heat insulating material. The evaporation unit 32 and the reforming unit 33 are arranged above the fuel cell 34. The combustion unit 35 is arranged between the evaporation unit 32, the reforming unit 33, and the fuel cell 34.

The evaporation unit 32 generates steam from the reformed water. Specifically, the evaporation unit 32 is heated by a combustion gas described later to evaporate the reformed water supplied from the water tank 14 to generate steam. Further, the evaporation unit 32 preheats the reforming raw material supplied from the supply source Gs.

The evaporation unit 32 mixes the steam generated in this manner with the preheated reforming raw material and supplies it to the reforming unit 33. Examples of the reforming raw material include reforming gas fuels such as natural gas and LP gas, and reforming liquid fuels such as kerosene, gasoline, and methanol.

The reforming unit 33 generates a reforming gas, which is a reforming fuel, from the reforming raw material and steam, and supplies the reforming gas to the fuel cell 34. Specifically, the reforming unit 33 is heated by the combustion gas described later and is supplied with the heat required for the steam reforming reaction, so that the mixed gas (raw material for reforming, steam) supplied from the evaporating unit 32 is supplied. ) To generate reformed gas.

The reforming section 33 is filled with a catalyst (for example, a Ru or Ni-based catalyst), and the mixed gas reacts with the catalyst and is reformed to produce a reformed gas containing hydrogen gas, carbon monoxide, and the like. It is produced (so-called steam reforming reaction). The reformed gas includes hydrogen, carbon monoxide, carbon dioxide, steam, unreformed natural gas (methane gas), and reformed water (steam) that was not used for reforming.

The fuel cell 34 generates electricity from the reforming gas and the oxidant gas. The fuel cell 34 is configured by stacking a plurality of cells (not shown) composed of a fuel electrode (not shown), an air electrode (oxidizing agent electrode; not shown), and an electrolyte interposed between the two electrodes. .. The fuel cell 34 is a solid oxide fuel cell, and uses zirconium oxide, which is a kind of solid oxide, as an electrolyte.

A reformed gas is supplied to the fuel electrode of the fuel cell 34. Fuel (reformed gas) flows on the fuel electrode side of the cell. Air (cathode air), which is an oxidant gas supplied by the cathode air blower 11c1, flows on the air electrode side of the cell.

In the combustion unit 35, the anode off gas (fuel off gas) from the fuel cell 34 and the cathode off gas (oxidizer off gas) from the fuel cell 34 are burned to generate combustion gas (flame 37). The combustion gas heats the evaporation unit 32 and the reforming unit 33.

Further, in the combustion unit 35, the anode off gas is burned to generate a relatively high temperature combustion exhaust gas. The combustion exhaust gas is led out to the heat exchanger 12. The combustion unit 35 sets the temperature inside the power generation module 30 to the operating temperature of the fuel cell 34.

The heat insulating member 36 is formed in a U-shaped cross section that opens the upper side. The heat insulating member 36 is formed of a heat insulating material such as seramics having a relatively high heat insulating property. The fuel cell 34 is arranged inside the heat insulating member 36.

The supported portion 40 is a pair of leg portions 40a and 40b provided on the lower side surface 31a of the power generation module 30. As shown in FIGS. 3 and 4, the pair of legs 40a and 40b are provided on both ends in the front-rear direction on the lower side surface 31a of the power generation module 30, respectively.

Each of the pair of legs 40a and 40b has the same configuration. The configuration of the first leg 40a arranged on the rear side of the pair of legs 40a and 40b is provided with the subscript "a", and the second leg 40a and 40b arranged on the front side of the pair of legs 40a and 40b. The subscript "b" is added to the structure of the leg portion 40b. Hereinafter, the configuration of the pair of legs 40a and 40b will be described only for the first leg 40a.

As shown in FIGS. 4, 7 to 9, the first leg portion 40a includes a mounting portion 41a, a first plate portion 42a, and a second plate portion 43a. The mounting portion 41a, the first plate portion 42a, and the second plate portion 43a are integrally formed by bending the sheet metal member.

The mounting portion 41a is provided so as to extend in the left-right direction in a U-shaped cross section that opens downward. The left-right length of the mounting portion 41a (corresponding to the left-right length of the supported portion 40) is approximately the same as the left-right length of the power generation module 30.

The first plate portion 42a is provided in a plate shape extending rearward from the lower end on the rear side of the mounting portion 41a, and one surface (lower side surface) is slidably (sliding) in contact with the support surface 71a described later. It is a thing. The first plate portion 42a is provided below the lower side surface 31a of the power generation module 30. The first plate portion 42a is provided so as to extend along the left-right direction over both ends of the supported portion 40 (mounting portion 41a) in the left-right direction.

As described above, the first plate portion 42a of the first leg portion 40a corresponds to the rear end side (rear direction: the first end side of the present invention) in the front-rear direction of the supported portion 40 (a pair of leg portions 40a, 40b). ) Is provided in a plate shape extending from the end portion toward the rear end side in the front-rear direction and extending along the left-right direction, and one surface (lower side surface) is slidably in contact with the support surface 71a described later. That is, the first plate portion 42a of the first leg portion 40a corresponds to the plate portion of the present invention.

Further, the first plate portion 42a includes a recess 42a1 as shown in FIGS. 4, 7 and 9. The recess 42a1 is formed so as to open toward the rear end side in the front-rear direction. The recess 42a1 is formed in a U shape when viewed from above. A plurality (two places) of the recesses 42a1 are provided in the first plate portion 42a. The recess 42a1 is provided at a position where it fits into the positioning portion 71c, which will be described later, in the left-right direction.

The second plate portion 43a is provided in a plate shape extending forward from the lower end on the front side of the mounting portion 41a and extending along the left-right direction, and one surface (lower side surface) is slidable with the support surface 71a described later. It comes into contact with (sliding). The second plate portion 43a is provided below the lower side surface 31a of the power generation module 30. Further, the second plate portion 43a is provided so as to extend along the left-right direction over both ends of the supported portion 40 (mounting portion 41a) in the left-right direction.

Next, the housing 10 will be described in detail. The housing 10 includes a plurality of panels 50 and a frame body 60.
Each of the plurality of panels 50 is provided so as to be removable. As shown in FIGS. 1 and 5, the plurality of panels 50 include a base panel 51, a rear side panel 52, a left side panel 53, a right side panel 54, a ceiling panel 55, and a front side panel 56 installed on the installation surface. Offering. Each of the panels 51 to 56 is mainly obtained by bending a sheet metal member.

As shown in FIG. 5, the base panel 51 constitutes the bottom wall of the housing 10, and the peripheral edge portion of the base panel 51 includes a bent portion 51a bent upward. The lower end of the frame body 60 is fixed to the bent portion 51a by a bolt or the like. The left and right side edges of the base panel 51 are provided with reinforcing leg portions 51b having lower edges extending outward, and the reinforcing leg portions 51b reinforce both left and right side portions of the base panel 51.

The rear side panel 52 constitutes the rear wall of the housing 10. The rear side surface panel 52 is detachably attached to the base panel 51 and the frame body 60 fixed to the base panel 51 by bolts or the like.

The left side panel 53 constitutes the left wall of the housing 10. The left side panel 53 is detachably attached to the base panel 51, the rear side panel 52 fixed to the base panel 51, and the frame body 60 by bolts or the like.

The right side panel 54 constitutes the right wall of the housing 10. The right side panel 54 is detachably attached to the base panel 51, the rear side panel 52 fixed to the base panel 51, and the frame body 60 by bolts or the like.

The ceiling panel 55 constitutes the ceiling wall of the housing 10. The peripheral edge of the ceiling panel 55 is formed in a shallow box shape having a bent portion 55a bent downward. The ceiling panel 55 is fitted onto the upper edges of the rear side panel 52, the left side panel 53, and the right side panel 54 fixed to the base panel 51. The ceiling panel 55 is detachably attached to the rear side panel 52 and the left side panel 53 by bolts or the like.

The front side panel 56 constitutes the front side wall of the housing 10. The front side panel 56 is detachably attached to the base panel 51, the left side panel 53 fixed to the base panel 51, the right side panel 54, and the frame body 60 by bolts or the like.

The plurality of panels 50 can be removed from the frame body 60 in the order of the front side panel 56, the left side panel 53, the right side panel 54, the ceiling panel 55, and the rear side surface panel 52. In a state where only the front side panel 56 of the plurality of panels 50 is removed, the above-mentioned fuel supply pipe 11a, reformed water supply line 11b, cathode air supply line 11c, exhaust pipe 11d and power supply line 20b are provided by a maintenance company. It is provided at a position where it can be attached to and detached from the power generation module 30.

The frame body 60 is formed by connecting a plurality of frames 61. Each of the plurality of frames 61 has an L-shaped cross section or a U-shaped cross section, and is formed in a rod shape extending in one direction. The plurality of frames 61 are connected to each other by using bolts B (see FIGS. 9 and 10) and the like. As shown in FIG. 6, the plurality of frames 61 include a front left pillar member 61a, a front middle pillar member 61b, a front right pillar member 61c, a rear left pillar member 61d, a rear middle pillar member 61e, a rear right pillar member 61f, and a front right pillar member 61f. It includes a lateral member 61 g, a rear lateral member 61h, a first support member 61i, and a second support member 61j.

The front left pillar member 61a is a frame erected along the vertical direction at the left end of the front end of the base panel 51. The front middle pillar member 61b is a frame erected along the vertical direction at approximately the center of the front end of the base panel 51. The front right pillar member 61c is a frame erected along the vertical direction at the right end of the front end of the base panel 51.

The rear left pillar member 61d is a frame erected along the vertical direction at the left end of the rear end of the base panel 51. The rear middle pillar member 61e is a frame erected along the vertical direction at approximately the center of the rear end of the base panel 51. The rear right pillar member 61f is a frame erected along the vertical direction at the right end of the rear end of the base panel 51.

The front right pillar member 61c, the rear right pillar member 61f, and the rear left pillar member 61d are erected along the vertical direction from the base panel 51 to the upper end portion of the housing 10. The front middle pillar member 61b, the front left pillar member 61a, and the rear middle pillar member 61e are erected from the base panel 51 to the central portion in the vertical direction of the housing 10.

The front lateral member 61g is arranged so as to extend along the left-right direction on the front side of the frame body 60, and is the central portion of the front right pillar member 61c, the upper end portion of the front middle pillar member 61b, and the upper end of the front left pillar member 61a. It is connected to the part. The front lateral member 61 g is formed in an L-shaped cross section with the inner side surfaces facing upward and rearward (see FIG. 10). The position of the upper end of the front lateral member 61g is set to be equal to or less than the upper side surfaces 61i1, 61j1 of the support members 61i, 61j, which will be described later. Further, the front right pillar member 61c is provided so as to be divisible into an upper first front right pillar member 61c1 and a lower second front right pillar member 61c2 at the connecting portion of the front horizontal member 61g.

The rear lateral member 61h is arranged so as to extend along the left-right direction on the rear side of the frame body 60, and is the central portion of the rear left pillar member 61d, the upper end portion of the rear middle pillar member 61e, and the rear right pillar member 61f. It is connected to the central part. The rear lateral member 61h is formed in an L-shaped cross section with the inner side surface facing downward and forward (see FIGS. 8 and 9).
Details of the first support member 61i and the second support member 61j will be described later.

Further, the frame body 60 includes a rectangular parallelepiped storage portion 70. The storage unit 70 stores the power generation module 30 (see FIGS. 2 and 5). The storage portion 70 is provided on the upper side of the frame body 60.

As shown by the broken line, the storage portion 70 is a space surrounded by the first front right pillar member 61c1, the rear left pillar member 61d, the rear right pillar member 61f, the horizontal members 61g, 61h, and the support members 61i, 61j. Is. As described above, each side surface of the storage unit 70 faces each side surface of the housing 10. Therefore, the above-mentioned panel is arranged so as to cover each side surface of the storage portion 70 on the side side. As shown in FIGS. 6 to 9, the storage portion 70 includes a support portion 71, a first open portion 72, and a second open portion 73.

The support portion 71 is provided at the bottom of the storage portion 70, and has a support surface 71a that supports the power generation module 30 at the supported portion 40 provided on the lower side surface 31a of the power generation module 30. The support portion 71 includes a first support member 61i, a second support member 61j, a holding portion 71b, and a positioning portion 71c.

The first support member 61i and the second support member 61j are formed in a rod shape having a support surface 71a on the side surface. The first support member 61i and the second support member 61j are formed in a U-shaped cross section that opens downward, and the upper side surfaces 61i1 and 61j1 are arranged so as to have the same height as each other. The support surface 71a is an upper side surface 61i1, 61j1 of the first support member 61i and the second support member 61j.

The support surface 71a, which is the upper side surface 61i1, 61j1 of the first support member 61i and the second support member 61j, is slidable with the lower side surface of each plate portion 42a, 43a, 42b, 43b in the supported portion 40 of the power generation module 30. (See FIGS. 8 to 10). As a result, each of the support members 61i and 61j slidably supports the supported portion 40 on the support surface 71a in the front-rear direction and the left-right direction.

The first support member 61i and the second support member 61j are arranged so as to extend over both ends in the front-rear direction of the storage portion 70. The first end portion (front end portion) of the first support member 61i and the second support member 61j is connected to the front lateral member 61g. Specifically, the first end portion of each of the support members 61i and 61j is connected to the front wall 61g2 of the front lateral member 61g so as to position the lower wall 61g1 of the front lateral member 61g downward (FIG. 10). reference). Further, the second end portion (rear end portion) of each of the support members 61i and 61j is connected to the rear lateral member 61h. Specifically, the second end portions of the support members 61i and 61j are connected to the rear wall 61h2 of the rear lateral member 61h so as to position the upper wall 61h1 of the rear lateral member 61h upward (FIG. 8). And see Figure 9).

Further, the first support member 61i and the second support member 61j are arranged so as to extend in parallel with each other along the front-rear direction. Further, the first support member 61i and the second support member 61j are arranged so as to be inside from both ends in the left-right direction of the power generation module 30 in a state where the power generation module 30 is supported (see FIG. 7).

Further, the support surface 71a (upper side surfaces 61i1, 61j1 of the support members 61i, 61j) accommodates the center of gravity G of the power generation module 30 in top view when the power generation module 30 is taken out from the storage portion 70 to the outside of the housing 10. When it is located inside the portion 70, it is arranged so as to support the supported portion 40. The center of gravity G is located at the center of the power generation module 30.

Specifically, the length of the power generation module 30 in the front-rear direction is slightly shorter than the length of the storage portion 70 in the front-rear direction, and the power generation module 30 is longer than the length L of the storage portion 70 in the left-right direction. The length in the left-right direction is between L / 2 and L, whereas the first support member 61i is separated from the right end of the storage portion 70 by about L / 4 in the left-right direction. Have been placed. Further, the first support member 61i and the second support member 61j are arranged so as to be separated by a length of about L / 2 in the left-right direction. Further, the second support member 61j is arranged so as to be separated from the left end of the storage portion 70 by a length of about L / 4 in the left-right direction.

As shown in FIG. 8, the holding portion 71b is provided on the rear side of the bottom portion of the supporting portion 71. The holding portion 71b is a first leg portion between the facing surface 71b1 facing the support surface 71a and the support surface 71a in a state where the power generation module 30 is housed in the storage portion 70 (see FIGS. 5 and 7). By sandwiching the first plate portion 42a of 40a, the first plate portion 42a is moved to the front end side in the front-rear direction (front direction: corresponding to the second end side of the present invention) and the left-right direction with respect to the support surface 71a. It is held so that it can be slidable. In this way, the holding portion 71b is provided by the support surface 71a and the facing surface 71b1.

The facing surface 71b1 is an inner side surface (a surface facing downward) of the upper wall 61h1 of the rear lateral member 61h. As described above, the upper wall 61h1 of the rear lateral member 61h is arranged above the upper side surfaces 61i1, 61j1 of the support members 61i, 61j, and the inner side surface (opposing surface 71b1) of the upper wall 61h1 is the support member 61i, respectively. It faces the upper side surfaces 61i1, 61j1 (support surface 71a) of 61j. The facing surface 71b1 is provided so as to be separated from the support surface 71a by the plate thickness of the first plate portion 42a material. The facing surface 71b1 slidably contacts the upper side surface of the first plate portion 42a.

The rear side of the holding portion 71b is covered with the rear wall 61h2 of the rear lateral member 61h. Further, the holding portion 71b is open in the front and left-right directions. As a result, the first plate portion 42a is slidably held in the front and left-right directions with respect to the holding portion 71b.

As shown in FIGS. 7 and 9, the positioning portion 71c is provided so that the recess 42a1 of the first plate portion 42a fits in the state where the power generation module 30 is housed in the storage portion 70, and is provided in the left-right direction of the power generation module 30. It is for positioning with respect to.

The positioning portion 71c is provided in a concave shape having a bottom portion at a portion above each of the support members 61i and 61j on the upper wall 61h1 of the rear lateral member 61h. The lower side surface 71c1 of the positioning portion 71c is provided so as to come into contact with the support surface 71a. The bolt B penetrates through the through hole 71c2 provided at the bottom of the positioning portion 71c, and the rear lateral member 61h and the support members 61i and 61j are fixed by the bolt B. By fitting the recess 42a1 into the positioning portion 71c, the sliding movement of the supported portion 40 in the left-right direction is restricted.

Further, in a state where the power generation module 30 is housed in the storage portion 70, the lower side surfaces of the plate portions 42a, 43a, 42b, 43b come into contact with the support surface 71a, and the first plate portion 42a of the first leg portion 40a is held. It is held by the portion 71b, and the recess 42a1 of the first plate portion 42a of the first leg portion 40a fits into the positioning portion 71c. In this state, as shown in FIG. 10, the power generation module 30 is fixed in the storage portion 70 by being fixed to the frame body 60 (each support member 61i, 61j) via the fixing member 80 by bolts B or the like. NS. The fixing member 80 connects the power generation module 30 and the frame body 60, and is provided by bending the sheet metal member.

As shown in FIG. 7, the first opening portion 72 is provided on the front side of the storage portion 70 in the front-rear direction, and by moving the power generation module 30 along the front-rear direction, the storage portion 70 and the outside of the housing 10 are provided. It is open to move between and. Specifically, the first open portion 72 is a space on the front side of the storage portion 70. By removing the front side panel 56 of the plurality of panels 50, the power generation module 30 between the storage portion 70 and the outside of the housing 10 can be taken out and stored via the first opening portion 72.

The second opening portion 73 is provided on the left-right direction side (both sides) of the storage portion 70, and moves between the storage portion 70 and the outside of the housing 10 by moving the power generation module 30 along the left-right direction. It is as open as possible. Specifically, the second opening portion 73 is a space on the left side and the right side of the storage portion 70. By removing one of the front side panel 56, the left side panel 53, and the right side panel 54 among the plurality of panels 50, the storage portion 70 and the outside of the housing 10 are separated from each other via the second opening portion 73. The power generation module 30 can be taken out and stored.

Next, in the cogeneration system 1 described above, with the cogeneration system 1 installed, there is sufficient space in front of the housing 10 to take out the power generation module 30, and the power generation module 30 is provided from the storage unit 70. To the outside of the housing 10 from the front of the storage unit 70 will be described.

In this case, first, only the front side panel 56 out of the plurality of panels 50 is removed. Subsequently, the fuel supply pipe 11a, the reformed water supply line 11b, the cathode air supply line 11c, the exhaust pipe 11d, and the power supply line 20b are removed from the power generation module 30. Further, the fixing member 80 (see FIG. 9) is removed. As a result, the power generation module 30 can be removed from the frame body 60.

Then, from the state in which the power generation module 30 is stored in the storage unit 70 (see FIGS. 5 and 7), the maintenance contractor faces the power generation module 30 forward, and the support surface 71a and the plate parts 42a, 43a, 42b, It is slid and moved so as to slide with the lower side surface of 43b. As a result, as shown in FIG. 11, the first plate portion 42a of the first leg portion 40a is disengaged from the holding portion 71b.

Further, the maintenance company slides the power generation module 30 forward, so that the power generation module 30 is taken out from the first opening portion 72. In this case, when the center of gravity G of the power generation module 30 is located inside the storage portion 70 in the top view, at least the lower side surface of the first leg portion 40a is the support member 61i, as shown in FIGS. 11 and 12. The power generation module 30 is supported by contacting the upper side surfaces 61i1, 61j1 (support surface 71a) of 61j.

On the other hand, when the power generation module 30 is stored in the storage unit 70 from the outside of the housing 10, the power generation module 30 is put into the storage unit 70 from the first opening portion 72 after adjusting the orientation of the power generation module 30. Then, the lower side surfaces of the plate portions 42a, 43a, 42b, and 43b are brought into contact with the support surface 71a to slide the power generation module 30, and the recess 42a1 of the first plate portion 42a of the first leg portion 40a is the positioning portion. The first plate portion 42a of the first leg portion 40a is sandwiched between the holding portions 71b so as to fit into the 71c.

Further, the frame body 60 and the power generation module 30 are fixed by the fixing member 80, and the fuel supply pipe 11a, the reformed water supply line 11b, the cathode air supply line 11c, the exhaust pipe 11d and the power supply line 20b are attached to the power generation module 30. .. As a result, the storage of the power generation module 30 in the storage unit 70 is completed. Finally, the front side panel 56 is attached.

Next, as shown in FIG. 13, since the cogeneration system 1 is installed in a relatively narrow place, the front side surface of the housing 10 and the wall W of the house are relatively close to each other, so that power is generated in front of the housing 10. A case where the power generation module 30 is taken out from the storage unit 70 toward the left when there is no space for taking out the module 30 will be described.

In this case, since there is a space as a carry-in path R of the cogeneration system 1 in the left-right direction of the cogeneration system 1, the power generation module 30 can be taken out from the left side of the storage unit 70 to the outside of the housing 10. can.

In this case, first, the front side panel 56 and the left side panel 53 of the plurality of panels 50 are removed. Subsequently, the arm of the maintenance contractor is turned to the front side surface of the housing 10, and the fuel supply pipe 11a, the reformed water supply line 11b, the cathode air supply line 11c, the exhaust pipe 11d, and the power supply line 20b are removed from the power generation module 30. It will be removed. Further, the fixing member 80 (see FIG. 9) is removed.

Then, the maintenance contractor removes the first plate portion 42a of the first leg portion 40a from the holding portion 71b as shown in FIG. 11 from the state in which the power generation module 30 is stored in the storage portion 70 (see FIG. 7). The power generation module 30 is slid forward so as to slide the support surface 71a and the lower side surfaces of the plate portions 42a, 43a, 42b, 43b. In this state, the lower side surfaces of the plate portions 42a, 43a, 42b, 43b of the second leg portion 40b are in contact with the support surface 71a.

Further, the maintenance contractor slides the power generation module 30 to the left so as to slide the support surface 71a and the lower side surfaces of the plate portions 42a, 43a, 42b, 43b. As a result, as shown in FIG. 13, the power generation module 30 is taken out from the second opening portion 73 on the left side. In this case, when the center of gravity G of the power generation module 30 is located inside the storage portion 70, the lower side surfaces of the plate portions 42a, 43a, 42b, 43b come into contact with at least the upper side surfaces 61i1, 61j1 of the second support member 61j. This supports the power generation module 30.

On the other hand, when the power generation module 30 is stored in the storage unit 70 from the outside of the housing 10, after adjusting the orientation of the power generation module 30, the power generation module 30 is put into the storage unit 70 from the second opening portion 73 on the left side, and each The lower side surfaces of the plate portions 42a, 43a, 42b, and 43b are brought into contact with the support surface 71a, and the power generation module 30 is slid to the right. Then, when the position of the power generation module 30 is approximately the same as the position where the power generation module 30 is stored in the left-right direction, the power generation module 30 is slid backward and the recess 42a1 of the first plate portion 42a of the first leg portion 40a is moved. The first plate portion 42a of the first leg portion 40a is sandwiched between the holding portions 71b so as to fit into the positioning portion 71c.

Further, as described above, the storage of the power generation module 30 in the storage portion 70 is completed, and finally the front side panel 56 and the left side panel 53 are attached.

According to the present embodiment, the cogeneration system 1 includes a rectangular parallelepiped housing 10 containing a power generation module 30 having a lower side surface 31a. The housing 10 is a frame body 60 formed by connecting a plurality of frames 61, and is a frame body 60 having a rectangular parallelepiped storage portion 70 for storing the power generation module 30, and a side side of the storage portion 70. A plurality of panels 50, which are arranged so as to cover each side surface and are detachably attached, are provided. The storage portion 70 is provided at the bottom of the storage portion 70, and is stored with a support portion 71 having a support surface 71a for supporting the power generation module 30 at a supported portion 40 provided on the lower side surface 31a of the power generation module 30. A first opening that is provided on the front side of the unit 70 in the front-rear direction and is movably opened between the inside of the storage unit 70 and the outside of the housing 10 by moving the power generation module 30 along the front-rear direction. A second unit is provided on the left-right side of the storage unit 72 and the storage unit 70, and is movably opened between the storage unit 70 and the outside of the housing 10 by moving the power generation module 30 along the left-right direction. It is provided with two opening portions 73.

According to this, after removing the plurality of panels 50, the power generation module 30 stored in the storage unit 70 is provided in the first opening portion 72 or the storage unit 70 provided on the front side in the front-rear direction in the storage unit 70. It can be taken out to the outside through the second opening portion 73 provided on the left-right direction side. Even if it is not possible to secure a space for taking out the power generation module 30 from the front-rear side of the storage unit 70 due to the space of the installation location of the cogeneration system 1, the cogeneration system 1 is carried into the storage unit 70 on the left-right side. There is a space used as the route R. Therefore, in this case, the power generation module 30 can be taken out from the left-right side of the storage unit 70. Therefore, maintenance of the power generation module 30 can be performed even when the cogeneration is installed in a relatively narrow place.

Further, the support portion 71 is formed in a rod shape provided with a support surface 71a on the side surface, and the first support member 61i and the second support member 61i and the second support portion 61 which slidably support the supported portion 40 in the front-rear direction and the left-right direction on the support surface 71a. A support member 61j is provided. The first support member 61i and the second support member 61j are arranged so as to extend over both ends in the front-rear direction of the storage portion 70 and extend parallel to each other along the front-rear direction, and support the power generation module 30. In the state, the power generation module 30 is arranged so as to be inside from both ends in the left-right direction.

According to this, the support portion 71 can be easily configured by the first support member 61i and the second support member 61j. Further, since the support portion 71 is composed of the first support member 61i and the second support member 61j formed in a rod shape, the contact area between the support portion 71 and the supported portion 40 can be made relatively small. Therefore, the slide movement of the power generation module 30 can be performed with a relatively low load.

Further, when the power generation module 30 is taken out from the storage portion 70 to the outside of the housing 10, the support surface 71a provides the supported portion 40 when the center of gravity G of the power generation module 30 is located inside the storage portion 70 in the top view. Arranged to support.

According to this, when the power generation module 30 is taken out, it is possible to prevent the power generation module 30 from tilting so that the center side of the storage portion 70 faces downward. Therefore, the power generation module 30 can be stably taken out from the storage unit 70.

Further, the supported portion 40 is provided in a plate shape extending from the end portion of the supported portion 40 on the rear end side in the front-rear direction toward the rear end side in the front-rear direction and extending along the left-right direction. The first plate portion 42a of the first leg portion 40a in which the direction is in sliding contact with the support surface 71a is provided. The support portion 71 sandwiches the first plate portion 42a of the first leg portion 40a between the facing surface 71b1 facing the support surface 71a and the support surface 71a in a state where the power generation module 30 is housed in the storage portion 70. By doing so, the holding portion 71b for holding the first plate portion 42a of the first leg portion 40a so as to be slidable in the front end side in the front-rear direction and the left-right direction with respect to the support surface 71a is provided.

According to this, the power generation module 30 is slidably moved so as to slide the support surface 71a and the lower side surfaces of the plate portions 42a, 43a, 42b, 43b, whereby the first leg portion 40a in the supported portion 40 The first plate portion 42a can be attached to and detached from the holding portion 71b. Therefore, the power generation module 30 can be stored in the storage unit 70 and taken out from the storage unit 70 relatively easily.

The first plate portion 42a of the first leg portion 40a includes a recess 42a1 formed so as to open toward the rear end side in the front-rear direction. The support portion 71 is provided so that the recess 42a1 is fitted in the state where the power generation module 30 is housed in the storage portion 70, and includes a positioning portion 71c for positioning the power generation module 30 in the left-right direction.

According to this, the positioning unit 71c can position the power generation module 30 in the left-right direction. Therefore, the power generation module 30 can be stored in the storage unit 70 relatively easily.

Although an example of the cogeneration system has been shown in the above-described embodiment, the present invention is not limited to this, and other configurations may be adopted. For example, the power generation module 30 of the cogeneration system 1 described above uses the fuel cell 34, but instead of the fuel cell 34, an internal combustion engine such as a gas engine (not shown) and a generator (not shown) are used to generate the power generation module. 30 may be configured.

Further, in the above-described embodiment, the support surface 71a is the upper side surfaces 61i1, 61j1 of the support members 61i, 61j, but instead, the entire bottom surface of the storage portion 70 may be used as the support surface. good. In this case, for example, a plate member having the entire one surface as a support surface is arranged at the bottom of the storage portion 70.

Further, in the above-described embodiment, the support portion 71 is provided with the positioning portion 71c, but instead of this, the positioning portion 71c may not be provided. In this case, the recesses 42a1 and 42b1 may not be provided in the first plate portions 42a and 42b.

Further, in the above-described embodiment, the support portion 71 includes the holding portion 71b, but instead of this, the holding portion 71b may not be provided. In this case, the first opening portion 72 may be provided on the rear side of the storage portion 70 as well. In this case, the first open portion 72 is provided on the front-rear side (both sides) of the storage portion 70. Further, in this case, the rear side panel 52 is removed and the power generation module 30 is moved rearward along the front-rear direction, so that the power generation module 30 moves between the inside of the storage portion 70 and the outside of the housing 10. It will be possible.

Further, in the above-described embodiment, the holding portion 71b is provided on the rear side of the bottom portion of the supporting portion 71, but instead, the holding portion 71b is provided on the front side of the bottom portion of the supporting portion 71. Is also good. In this case, the first opening portion 72 is provided only on the rear side of the storage portion 70 in the front-rear direction. Further, in this case, the second plate portion 43b of the second leg portion 40b corresponds to the plate portion of the present invention. That is, in this case, the second plate portion 43b of the second leg portion 40b is directed from the end portion of the supported portion 40 (a pair of leg portions 40a, 40b) on the front end side in the front-rear direction toward the front end side in the front-rear direction. It is provided in a plate shape that extends and extends along the left-right direction, and one surface is in sliding contact with the support surface 71a. Further, the recess is formed in the second plate portion 43b of the second leg portion 40b so as to open toward the front end side in the front-rear direction. Further, the position of the recess is set according to the positions of the support members 61i and 61j, the holding portion 71b and the positioning portion 71c.

Further, in the above-described embodiment, one of the lateral direction and the longitudinal direction of the storage unit 70 in the top view corresponds to the front-rear direction, and the other direction in the lateral direction and the longitudinal direction of the storage unit 70 in the top view corresponds to the front-rear direction. It corresponds to the left-right direction, but instead, one of the lateral direction and the longitudinal direction in the top view of the storage portion 70 corresponds to the left-right direction, and the lateral direction and the longitudinal direction in the top view of the storage portion 70. The other direction may correspond to the front-back direction.

In this case, specifically, the support members 61i and 61j are provided so as to be parallel to each other along the left-right direction. That is, in this case, the support members 61i and 61j are arranged so as to extend across both ends of the storage portion 70 in the left-right direction (longitudinal direction) and extend parallel to each other along the left-right direction. In this case, the front lateral member 61g is arranged along one of the left end and the right end of the bottom portion of the storage portion 70 along the front-rear direction (short direction), and the first end portion of each of the support members 61i and 61j is formed. At the same time, the rear lateral member 61h is arranged along the front-rear direction to the other of the left end and the right end of the bottom portion of the storage portion 70, and the second end portions of the support members 61i and 61j are connected to each other. Further, the support members 61i and 61j are arranged so as to be inside from both ends in the front-rear direction of the power generation module 30 in a state where the power generation module 30 is supported.

Further, in this case, the pair of leg portions 40a and 40b, which are the supported portions 40, are provided on both ends of the lower side surface 31a of the power generation module 30 in the left-right direction so as to extend along the front-rear direction. In this case, the first plate portion 42a is from one of the left end side end portion and the right end side end portion in the left-right direction of the pair of leg portions 40a and 40b, and the left end side (left side) in the left-right direction. It is provided in a plate shape that extends toward one of the right end side (right side) and extends along the front-rear direction.

Further, in this case, the holding portion 71b, the positioning portion 71c, and the recess 42a1 are provided on either the left end side or the right end side in the left-right direction of the storage portion 70, respectively. In this case, the recesses 42a1, 42b1 are provided in the first plate portions 42a, 42b of the pair of leg portions 40a, 40b so as to open toward one of the left end side and the right end side in the left-right direction. .. Further, in this case, the positioning unit 71c positions the power generation module 30 in the front-rear direction. Specifically, the first plate portion 42a, and thus the holding portion 71b, the positioning portion 71c, and the recess 42a1 are provided on the side in the left-right direction in which the rear lateral member 61h is arranged.

Further, in the above-described embodiment, the power generation module 30 is taken out from the storage unit 70 via the second opening portion 73 on the left side of the storage unit 70, but instead, the power generation module 30 is placed on the right side of the storage unit 70. It may be taken out from the storage part 70 through the second opening part 73 of the above. In this case, the first front right column member 61c1 is removed from the frame body 60.

Further, in the above-described embodiment, the supported portion 40 is a pair of leg portions 40a and 40b, but instead of this, the power generation module 30 does not include the pair of leg portions 40a and 40b, and the supported portion 40 May be the lower side surface 31a of the power generation module 30. In this case, the plate portion sandwiched between the holding portions 71b extends rearward from the rear end of the lower end of the casing of the power generation module 30, and the lower side surface is formed in a plate shape that is flush with the lower side surface 31a of the power generation module 30. ..

Further, as long as the gist of the present invention is not deviated, the shapes of the housing 10, the frame body 60, the plurality of frames 61, the storage portion 70 and the support surface 71a, the support portion 71 (each support member 61i, 61j), and the cover. The shapes and numbers of the support portion 40, the holding portion 71b, the recess 42a1 and the positioning portion 71c may be changed.

1 ... Cogeneration system, 10 ... Housing, 11 ... Power generation module, 31 ... Casing, 31a ... Lower side surface, 34 ... Fuel cell, 40 ... Supported part, 40a ... First leg part, 40b ... Second leg part, 42a ... First plate part (plate part), 42a1 ... Recessed part, 43a ... Second plate part, 50 ... Multiple panels, 60 ... Frame body, 61 ... Frame, 61i ... First support member, 61i1, 61j1 ... Upper side surface , 61j ... Second support member, 70 ... Storage part, 71 ... Support part, 71a ... Support surface, 71b ... Holding part, 71b1 ... Opposing surface, 71c ... Positioning part, 72 ... First open part, 73 ... Second open Department, G ... Center of gravity.

Claims (5)

It is a cogeneration system equipped with a rectangular parallelepiped housing that houses a power generation module with a lower side surface.
The housing is
A frame body formed by connecting a plurality of frames and having a rectangular parallelepiped storage portion for storing the power generation module, and the frame body.
A plurality of detachably attached panels, which are arranged so as to cover each side surface of the storage portion, are provided.
The storage unit
A support portion provided at the bottom of the storage portion and a supported portion provided on the lower side surface of the power generation module, which has a support surface for supporting the power generation module, and a support portion.
The inside of the storage portion and the inside of the storage portion and the said The first opening that is movable between the outside of the housing and the first opening
The storage unit and the storage unit are provided by being provided on the other side of the storage unit in the lateral direction and the longitudinal direction in the top view of the storage unit, and by moving the power generation module along the other direction. A cogeneration system equipped with a second opening that is movable between the outside of the housing. The support portion
It is formed in a rod shape with the support surface provided on the side surface, and includes a first support member and a second support member that slidably support the supported portion on the support surface in the lateral direction and the longitudinal direction.
The first support member and the second support member
The accommodating portion is arranged so as to extend over both ends in the one direction and extend parallel to each other along the one direction, and in a state of supporting the power generation module, the other in the power generation module. The cogeneration system according to claim 1, wherein the cogeneration system is arranged so as to be inside from both ends in the direction of. The support surface supports the supported portion when the center of gravity of the power generation module is located inside the storage portion in a top view when the power generation module is taken out from the storage portion to the outside of the housing. The cogeneration system according to claim 1 or 2. The supported portion is
It is provided in a plate shape extending from the end on the first end side in one direction of the supported portion toward the first end side in the one direction and extending along the other direction. It is provided with a plate portion in which the direction slides into contact with the support surface.
The support portion
In a state where the power generation module is housed in the storage portion, the plate portion is sandwiched between the facing surface facing the support surface and the support surface so that the plate portion can be attached to the support surface. The cogeneration system according to any one of claims 1 to 3, further comprising a holding portion that is slidably held on the second end side in the one direction and in the other direction. The plate portion includes a recess formed so as to open toward the first end side in one of the directions.
According to claim 4, the support portion is provided so that the recess is fitted in the state where the power generation module is housed in the storage portion, and includes a positioning portion for positioning the power generation module in the other direction. The described cogeneration system.

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