JP2021148049A - Enclosure and power generation facility - Google Patents

Abstract

To restrain occurrence of noise caused by transmission of vibration from a vibration source in an enclosure and a power generation facility.SOLUTION: An enclosure inside which a vibration source is arranged comprises: a base plate installed on a floor surface, and on which the vibration source is mounted; a case surrounding the periphery of the vibration source, separated from the base plate, and arranged on the floor surface; an air inlet part provided on an upstream side in an air flow direction in the case; and an air outlet part provided on a downstream side in the air flow direction in the case.SELECTED DRAWING: Figure 1

Description

The present disclosure relates to an enclosure for accommodating a power generation unit and the like, and a power generation facility including an enclosure.

The power generation equipment is configured by arranging a power generation unit inside a housing called an enclosure. The enclosure is placed inside or outside the building. The power generation unit has a generator and a power generation source for driving the generator. The enclosure acts as a soundproof cover to reduce noise generated by generators and power sources. In addition, a blower is arranged inside the enclosure, and air sucked from the outside by the blower is supplied to the power generation unit. The power generation unit is cooled by air from the outside. The air that cooled the power generation unit is discharged to the outside.

As such a power generation facility, for example, there is one described in Patent Document 1 below.

Japanese Unexamined Patent Publication No. 2006-125260

A conventional power generation facility is configured by installing a base plate having a vibration isolator on the floor surface and mounting a power generation unit and an enclosure on the base plate. The vibration of the power generation unit is absorbed by the vibration isolator of the base plate, and the vibration transmission to the floor surface is suppressed. However, since the enclosure is mounted on the base plate, the vibration of the power generation unit is transmitted to the enclosure via the base plate, and the enclosure vibrates. Therefore, there is a problem that noise is generated due to the vibration of the enclosure.

The present disclosure is to solve the above-mentioned problems, and an object of the present invention is to provide an enclosure and a power generation facility for suppressing the generation of noise due to the transmission of vibration from a vibration source.

The enclosure of the present disclosure for achieving the above object is an enclosure in which a vibration source is arranged inside, and surrounds a base plate on the floor on which the vibration source is mounted and the periphery of the vibration source. A housing arranged on the floor surface away from the base plate, an air inlet portion provided on the upstream side of the housing in the air flow direction, and a housing provided on the downstream side of the housing in the air flow direction. It is provided with an air outlet.

Further, the power generation equipment of the present disclosure includes the enclosure and a power generation unit as the vibration source arranged inside the enclosure.

Further, in the power generation equipment of the present disclosure, the first unit in which the engine and the generator are mounted on the first base plate and the periphery is surrounded by the first housing, and the radiator is mounted on the second base plate and the surroundings are surrounded. The air was sucked from the air inlet, the second unit surrounded by the second housing, the third unit arranged above the first unit and the second unit and the silencer mounted on the third base plate. The first unit includes a fourth unit having an intake duct for supplying air to the first housing, and a fifth unit having an exhaust duct for discharging air from the second housing from an air outlet portion. The second unit, the third unit, the fourth unit, and the fifth unit are detachably provided, respectively.

According to the enclosure and the power generation facility of the present disclosure, it is possible to suppress the generation of noise due to the transmission of vibration from the vibration source.

FIG. 1 is a side view showing a power generation facility to which the enclosure of the present embodiment is applied. FIG. 2 is a plan view of the power generation facility. FIG. 3 is an exploded perspective view of the enclosure. FIG. 4 is a sectional view taken along line IV-IV of FIG. 2 showing the positional relationship between the lower base plate on which the power generation unit is mounted and the enclosure. FIG. 5 is a VV cross-sectional view of FIG. 2 showing the positional relationship between the lower base plate on which the power generation unit is mounted and the enclosure. FIG. 6 is a sectional view taken along line VI-VI of FIG. 1 showing the positional relationship between the lower base plate on which the power generation unit is mounted and the enclosure.

Preferred embodiments of the present disclosure will be described in detail below with reference to the drawings. It should be noted that the present disclosure is not limited by this embodiment, and when there are a plurality of embodiments, the present embodiment also includes a combination of the respective embodiments. In addition, the components in the embodiment include those that can be easily assumed by those skilled in the art, those that are substantially the same, that is, those in a so-called equal range.

[Power generation equipment]
FIG. 1 is a side view showing a power generation facility to which the enclosure of the first embodiment is applied, FIG. 2 is a plan view of the power generation facility, and FIG. 3 is an exploded perspective view of the enclosure. In the following description, the longitudinal direction of the power generation facility (horizontal direction in FIGS. 1 and 2) is the X direction, the width direction of the power generation facility (vertical direction in FIG. 2) is the Y direction, and the height direction of the power generation facility (FIG. 2). The vertical direction of 1) will be described as the Z direction.

In the present embodiment, as shown in FIGS. 1 to 3, the power generation facility 10 is arranged inside or outside the building (not shown). The power generation facility 10 includes an enclosure 11 and a power generation unit 12. The power generation unit 12 is arranged inside the enclosure 11.

The enclosure 11 includes a lower base plate (base plate) 21, a first housing 22, a second housing 23, an upper base plate 24, an intake duct 25, and an exhaust duct 26. In the enclosure 11, the lower base plate 21, the first housing 22, the second housing 23, the upper base plate 24, the intake duct 25, and the exhaust duct 26 are arranged linearly along the X direction. The second housing 23 and the exhaust duct 26 may be integrally configured instead of being separate.

The lower base plate 21 is installed and fixed on the floor surface 101 along the X direction. The lower base plate 21 has a T-shaped plan view and has a vibration isolator 30. The lower base plate 21 is installed on the floor surface 101 via the vibration isolator 30. The anti-vibration device 30 is a plurality of anti-vibration rubbers 30a, and is attached to the lower portion of the lower base plate 21 at predetermined intervals. However, the vibration isolator 30 is not limited to this configuration. The lower base plate 21 has a narrow portion 21a and a wide portion 21b. The narrow portion 21a and the wide portion 21b are integrally provided.

The first housing 22 has a rectangular parallelepiped box shape. The length of the first housing 22 in the X direction is shorter than that of the lower base plate 21, and the width in the Y direction is longer than that of the lower base plate 21. The first housing 22 has left and right side wall portions 31, 32, a ceiling portion 33, and a rear wall portion 34. The lower side of the first housing 22 is opened, a front connecting opening 35 is formed at one end in the X direction, and a rear connecting opening 36 is formed at the upper end at the other end in the X direction. The first housing 22 is arranged so as to cover the narrow portion 21a of the lower base plate 21. The first housing 22 is arranged so that the lower ends of the side wall portions 31, 32 and the rear wall portion 34 are separated from the narrow portion 21a of the lower base plate 21 by predetermined distances in the X and Y directions. In the first housing 22, the side wall portions 31, 32 and the lower end portions of the rear wall portion 34 are placed on the floor surface 101 via the installation portion 37 and fixed.

The second housing 23 has a rectangular parallelepiped box shape. The length of the second housing 23 in the X direction is shorter than that of the lower base plate 21, and the width in the Y direction is longer than that of the lower base plate 21. The second housing 23 has left and right side wall portions 41 and 42, a ceiling portion 43, and a pair of rear wall portions 44a and 44b. The lower part of the second housing 23 is opened, a front connecting opening 45 is formed at one end in the X direction, and a rear connecting opening 46 is formed at the other end in the X direction. The second housing 23 is arranged so as to cover the wide portion 21b of the lower base plate 21. The second housing 23 is arranged so that the lower ends of the side wall portions 41 and 42 are separated from the wide portion 21b of the lower base plate 21 by a predetermined distance in the Y direction. In the second housing 23, the side wall portions 41, 42 and the lower ends of the rear wall portions 44a, 44b are placed on the floor surface 101 via the installation portion 47 and fixed. In the first housing 22 and the second housing 23, the front connecting opening 35 and the rear connecting opening 46 are connected without a gap.

The upper base plate 24 has a rectangular plate shape in a plan view. The upper base plate 24 is installed and fixed on the ceiling portions 33 and 43 of the first housing 22 and the second housing 23. The upper base plate 24 is formed with a circular through hole 51 at an end portion in the longitudinal direction.

The intake duct 25 has a square cylinder shape, and the side view is L-shaped. The intake duct 25 has a first duct main body 25a, a second duct main body 25b, and a pair of third duct main bodies 25c. The first duct main body 25a is arranged along the Z direction, and an air inlet portion 61 is provided at one end (lower end) in the Z direction. The second duct main body 25b is arranged along the X direction, and one end thereof is integrally connected to the other end (upper end portion) of the first duct main body 25a in the Z direction. The pair of third duct main bodies 25c are arranged along the Y direction, and one end thereof is integrally connected to both sides of the other end portion of the second duct main body 25b. The pair of third duct main bodies 25c is provided with an air inlet portion 62 at the lower end of the other end portion. Further, in the second duct main body 25b, a connecting opening 63 is formed in the lower portion of the other end portion. In the intake duct 25, the connecting opening 63 is connected to the rear connecting opening 36 of the first housing 22 without a gap. Here, the width of the first duct main body 25a and the second duct main body 25b in the intake duct 25 in the Y direction is substantially the same as the width of the first housing 22 in the Y direction. Further, the width of the third duct main body 25c in the intake duct 25 in the Y direction is substantially the same as the width of the second housing 23 in the Y direction.

The exhaust duct 26 has a square tubular shape. The exhaust duct 26 is arranged along the Z direction, and the lower side is opened. The exhaust duct 26 has a connecting opening 71 formed on the first housing 22 side of one end (lower end) in the Z direction, and both sides in the Y direction and one in the X direction at the other end (upper end) in the Z direction. Air outlets 72 are provided facing each other. The exhaust duct 26 may be provided with an air outlet portion 72 facing only one side in the X direction. In the exhaust duct 26, the connecting opening 71 is connected to the front connecting opening 45 of the second housing 23 without a gap. The lower end of the exhaust duct 26 is placed on the floor surface 101 via the installation portion 73 and fixed. Here, the width of the exhaust duct 26 in the Y direction is substantially the same as the width of the first housing 22 in the Y direction.

The power generation unit 12 includes a generator 81 and a power generation source 82 as vibration sources. The power generation source 82 includes an engine 91, a radiator 92, a cooling fan (blower) 93, an exhaust pipe 94, and a silencer 95.

The engine 91 is, for example, a diesel engine. The engine 91 takes heat and lowers the temperature by flowing cooling water inside. The radiator 92 is an air-cooled type and takes heat from the cooling water to lower the temperature. The engine 91 and the radiator 92 are connected by a circulation line (not shown). The water pump provided in the engine 91 circulates the cooling water between the engine 91 and the radiator 92 via a circulation line. The engine 91 is cooled by the cooling water to lower the temperature, and the high temperature engine cooling water is cooled by the radiator 92 to lower the temperature.

The cooling fan 93 is provided in the engine 91 and drives and rotates in synchronization with the rotation of the engine 91. The cooling fan 93 is arranged between the engine 91 and the radiator 92. That is, the cooling fan 93 is provided on the downstream side of the engine 91 in the air flow direction. When the cooling fan 93 is driven and rotated, an air flow is generated from the engine 91 toward the radiator 92. The radiator 92 has a large number of tubes through which cooling water flows. The cooling water flowing through a large number of tubes is cooled by contact with the air flow generated by the cooling fan 93.

The engine 91 is connected to an exhaust pipe 94 that discharges exhaust gas. The exhaust pipe 94 is provided with a silencer 95.

The generator 81 is driven and connected to the engine 91 of the power generation source 82. The generator 81 is driven by transmitting the rotational driving force of the engine 91. The generator 81 generates electric power by driving it.

The generator 81 and the power generation source 82 constituting the power generation unit 12 are mounted on the lower base plate 21 and the upper base plate 24. The engine 91, the radiator 92, the cooling fan 93, and the generator 81 are mounted on the lower base plate 21. The silencer 95 is mounted on the upper base plate 24. The exhaust pipe 94 is arranged along the Z direction so as to connect the engine 91 and the silencer 95. At this time, the exhaust pipe 94 having one end connected to the engine 91 is connected to the silencer 95 with the other end penetrating the through hole 51 of the upper base plate 24. Further, the generator 81 is mounted on the lower base plate 21 in a state of being connected to the engine 91. The silencer 95 may be directly mounted on the ceiling portions 33 and 43 of the first housing 22 and the second housing 23 without providing the upper base plate 24.

Further, the first housing 22 and the second housing 23 are arranged on the lower base plate 21 with the engine 91, the radiator 92, the cooling fan 93, and the generator 81 mounted on the lower base plate 21. The first housing 22 surrounds the engine 91 and the generator 81. The second housing 23 surrounds the radiator 92 and the cooling fan 93. The intake duct 25 is connected to the first housing 22, and the exhaust duct 26 is connected to the second housing 23. Therefore, an air flow path is formed by the intake duct 25, the second housing 23, the first housing 22, and the exhaust duct 26.

FIG. 4 is a sectional view taken along the line IV-IV of FIG. 2 showing the positional relationship between the lower base plate on which the power generation unit is mounted and the enclosure, and FIG. 5 shows the positional relationship between the lower base plate on which the power generation unit is mounted and the enclosure. FIG. 6 is a sectional view taken along line VV of FIG. 2, and FIG. 6 is a sectional view taken along line VI-VI of FIG. 1 showing the positional relationship between the lower base plate on which the power generation unit is mounted and the enclosure.

In the present embodiment, as shown in FIGS. 4 to 6, a generator 81 and a power generation source 82 (engine 91, which are installed on the lower base plate 21 on the floor surface 101 and are vibration sources on the lower base plate 21). A radiator 92 and a cooling fan 93) are installed. The first housing 22 and the second housing 23 are separated from the periphery of the lower base plate 21 by a predetermined distance so as to surround the generator 81 and the power generation source 82 on the lower base plate 21, and the floor surface 101 Will be installed in. The vibration isolator 30 is provided on the lower base plate 21.

The power generation source 82 has an engine 91 having a narrow width and a radiator 92 having a width wider than that of the engine 91. The first housing 22 surrounds the engine 91, and the second housing 23 surrounds the radiator 92 and the cooling fan 93. The lower base plate 21 has a narrow portion 21a and a wide portion 21b wider than the narrow portion 21a. The engine 91 is mounted on the narrow portion 21a, and the radiator 92 is mounted on the wide portion 21b. The second housing 23 is wider than the first housing 22.

That is, as shown in FIGS. 4 and 6, a gap X1 is provided between the narrow portion 21a of the lower base plate 21 and the installation portion 37 of the first housing 22 in the X direction. In the X direction, a gap X2 is provided between the wide portion 21b of the lower base plate 21 and the installation portion 73 of the exhaust duct 26. As shown in FIGS. 5 and 6, gaps Y1 and Y2 are provided between the narrow portion 21a of the lower base plate 21 and the installation portion 37 of the first housing 22 in the Y direction. In the Y direction, gaps Y3 and Y4 are provided between the wide portion 21b of the lower base plate 21 and the installation portion 37 of the first housing 22 and the installation portion 73 of the exhaust duct 26. That is, the first housing 22 and the second housing 23 do not come into contact with the lower base plate 21 on which the generator 81 and the power generation source 82 (engine 91, radiator 92, cooling fan 93), which are vibration sources, are mounted. It is installed on the floor surface 101 separated from the lower base plate 21 by a predetermined distance.

In the present embodiment, the enclosure 11 is composed of a plurality of (five in this embodiment) units U1, U2, U3, U4, U5. The first unit U1 is a unit in which the engine 91 and the generator 81 are mounted on the narrow portion (first base plate) 21a of the lower base plate 21 and the periphery thereof is surrounded by the first housing 22. The second unit U2 is a unit in which the radiator 92 and the cooling fan 93 are mounted on the wide portion (second base plate) 21b of the lower base plate 21 and the periphery thereof is surrounded by the second housing 23. The third unit U3 is a unit that is arranged above the first unit U1 and the second unit U2 and has the silencer 95 mounted on the upper base plate (third base plate) 24. The fourth unit U4 is a unit having an intake duct 25 for supplying the air sucked from the air inlets 61 and 62 to the first housing 22. The fifth unit U5 is a unit having an exhaust duct 26 for discharging the air of the second housing 23 from the air outlet portion 72.

The first unit U1, the second unit U2, the third unit U3, the fourth unit U4, and the fifth unit U5 are detachably provided, respectively. That is, the first unit U1, the second unit U2, the third unit U3, the fourth unit U4, and the fifth unit U5 are manufactured, for example, in a factory. Each unit manufactured in the factory is transported to the installation site of the power generation facility 10 individually or together. Each unit U1, U2, U3, U4, U5 transported to the installation site is assembled as a unit in order at this installation site. In the present embodiment, the engine 91, the radiator 92, the cooling fan 93, and the generator 81 are mounted on the lower base plate 21 and surrounded by the first housing 22 and the second housing 23. Therefore, the lower base plate 21, the engine 91, the radiator 92, the cooling fan 93, the generator 81, and the first housing 22 are used as the first unit U1, the second housing 23 is used as the second unit U2, or the lower base plate 21 is used. The engine 91, the radiator 92, the cooling fan 93, the generator 81, and the second housing 23 may be the second unit U2, and the first housing 22 may be the first unit U1. However, the configuration is not limited to this, and for example, the narrow portion 21a and the wide portion 21b of the lower base plate 21 may be configured as separate members.

[Operation of power generation equipment]
As shown in FIGS. 1 and 2, when the engine 91 constituting the power generation source 82 is driven in the power generation facility 10, the water pump operates synchronously and the cooling water is circulated between the engine 91 and the radiator 92. Let me. Further, when the engine 91 is driven, the cooling fan 93 operates synchronously to cause air to flow in the enclosure 11.

That is, when the cooling fan 93 operates, the internal air flows from the engine 91 side to the radiator 92 side. Then, a negative pressure is generated on the engine 91 side of the cooling fan 93. The generated negative pressure acts on the intake duct 25 from the first housing 22 and the second housing 23, and external air is sucked from the air inlet portions 61 and 62. The external air sucked from the air inlets 61 and 62 is introduced into the first housing 22 and the second housing 23 through the intake duct 25, and is discharged to the outside from the air outlet 72 through the exhaust duct 26. ..

The air flowing inside the first housing 22 and the second housing 23 is guided to the radiator 92. The radiator 92 cools the cooling water circulating between the engine 91 and the radiator 92 to lower the temperature. Therefore, the temperature of the engine 91 is lowered by being cooled by the cooling water whose temperature has been lowered.

Further, when the engine 91 is driven, the generator 81 is driven, and the generator 81 generates electric power. Then, the temperatures of the generator 81 and the power generation source 82, which are heat sources, rise. However, the generator 81 and the power generation source 82 whose temperature has risen are cooled by the air flowing in the first housing 22 and the second housing 23.

Further, the generator 81 and the power generation source 82 generate noise when they are driven. The enclosure 11 is provided with a sound absorbing material inside, for example, and absorbs the generated noise to suppress leakage to the outside.

[Action and effect of this embodiment]
The enclosure according to the first aspect is the enclosure 11 in which the power generation unit 12 as a vibration source is arranged inside, the lower base plate 21 installed on the floor surface 101 on which the power generation unit 12 is mounted, and the power generation unit 12. The first housing 22 and the second housing 23 which surround the periphery and are arranged on the floor surface 101 away from the lower base plate 21, and the upstream in the air flow direction in the first housing 22 and the second housing 23. The air inlet portions 61 and 62 provided on the side and the air outlet portions 72 provided on the downstream side in the air flow direction in the first housing and the second housing 23 are provided.

In the enclosure according to the first aspect, the lower base plate 21 is installed on the floor surface 101, the power generation unit 12 is mounted, and the first housing 22 and the second housing 23 surround the power generation unit 12. It is arranged on the floor surface 101 away from the lower base plate 21. Therefore, when the power generation unit 12 is driven, the lower base plate 21 vibrates, but since the first housing 22 and the second housing 23 are arranged apart from the lower base plate 21, the vibration is suppressed. .. As a result, it is possible to suppress the generation of noise due to the transmission of vibration from the power generation unit 12 as a vibration source.

The enclosure according to the second aspect includes an engine 91 as a first vibration source, a radiator 92 as a second vibration source wider than the engine 91, and a first housing 22 surrounding the engine 91. A second housing 23, which is wider than the first housing 22, is provided so as to surround the radiator 92. As a result, the housing is divided into a first housing 22 that surrounds the periphery of the engine 91 and a second housing 23 that surrounds the radiator 92, and the width of the first housing 22 is the width of the engine 91. The size of the enclosure 11 can be reduced accordingly.

The enclosure according to the third aspect is provided with a narrow portion 21a and a wide portion 21b as a lower base plate 21, an engine 91 is mounted on the narrow portion 21a, and a radiator 92 is mounted on the wide portion 21b. As a result, the lower base plate 21 is provided with the narrow portion 21a on which the engine 91 is mounted and the wide portion 21b on which the radiator 92 is mounted, so that the width of the lower base plate 21 can be reduced to reduce the size of the enclosure 11. Can be planned.

The enclosure according to the fourth aspect is provided with an intake duct (intake unit) 25 having air inlet portions 61 and 62 and being detachably connected to the upstream side in the air flow direction in the first housing 22. As a result, the intake duct 25 can be manufactured separately from the first housing 22, and the intake duct 25 can be easily transported from the manufacturing factory to the installation location.

The enclosure according to the fifth aspect is provided with an exhaust duct (exhaust unit) 26 having an air outlet portion 72 and being detachably connected to the downstream side in the air flow direction of the second housing 23. As a result, the exhaust duct 26 can be manufactured separately from the second housing 23, and the exhaust duct 26 can be easily transported from the manufacturing factory to the installation location.

In the enclosure according to the sixth aspect, the vibration isolator 30 is provided on the lower base plate 21. As a result, when the power generation unit 12 is driven, the lower base plate 21 vibrates, but the vibration is absorbed by the vibration isolator 30, and the first housing 22 and the second housing 23 are separated from the lower base plate 21. The vibrations of the first housing 22 and the second housing 23 can be suppressed.

The power generation equipment according to the seventh aspect includes an enclosure 11 and a power generation unit 12 arranged inside the enclosure 11. As a result, when the power generation unit 12 is driven, the lower base plate 21 vibrates, but since the first housing 22 and the second housing 23 are arranged apart from the lower base plate 21, the vibration is suppressed. NS. As a result, it is possible to suppress the generation of noise due to the transmission of vibration from the power generation unit 12 as a vibration source.

The power generation facility according to the eighth aspect is the first unit in which the engine 91 and the generator 81 are mounted on the narrow portion (first base plate) 21a of the lower base plate 21 and the periphery thereof is surrounded by the first housing 22. U1, the second unit U2 in which the radiator 92 is mounted on the wide portion (second base plate) 21b of the lower base plate and the periphery is surrounded by the second housing 23, and the first unit U1 and the second unit U2. The third unit U3, which is arranged at the upper part and has the silencer 95 mounted on the upper base plate (third base plate) 24, and the intake air that supplies the air sucked from the air inlets 61 and 62 to the first housing 22. A fourth unit U4 having a duct 25 and a fifth unit U5 having an exhaust duct 26 for discharging the air of the second housing 23 from the air outlet portion 72 are provided, and the first unit U1, the second unit U2, and the third unit are provided. The unit U3, the fourth unit U4, and the fifth unit U5 are detachably provided. As a result, it is possible to suppress the generation of noise due to the transmission of vibration from the power generation unit 12 as a vibration source.

In the above-described embodiment, the engine 91 is surrounded by the first housing 22, and the radiator 92 and the cooling fan 93 are surrounded by the second housing 23, but the present invention is not limited to this configuration. For example, the engine 91 and the cooling fan 93 may be surrounded by the first housing 22, and the radiator 92 may be surrounded by the second housing 23.

Further, in the above-described embodiment, the narrow portion 21a and the wide portion 21b are integrally provided on the lower base plate 21, but the narrow portion 21a and the wide portion 21b are provided separately on the floor surface 101. It may be arranged apart.

Further, in the above-described embodiment, the cooling fan 93 constituting the power generation source 82 is applied as the blower, but the present invention is not limited to this configuration, and a separate blower may be provided.

Further, in the above-described embodiment, the heat source is the power generation unit 12, the power generation unit 12 is the generator 81 and the power generation source 82, and the power generation source 82 is the engine 91, but the present invention is not limited to this configuration. For example, as the power generation source 82, for example, a steam turbine, a gas turbine, a fuel cell, or the like may be applied.

10 Power generation equipment 11 Enclosure 12 Power generation unit (vibration source)
21 Lower base plate 21a Narrow part (1st base plate)
21b Wide part (second base plate)
22 1st housing 23 2nd housing 24 Upper base plate (3rd base plate)
25 Intake duct 25a 1st duct body 25b 2nd duct body 25c 3rd duct body 26 Exhaust duct 30 Anti-vibration device 31, 32 Side wall 33 Ceiling 34 Rear wall 35 Front connection opening 36 Rear connection opening 37 Installation part 41, 42 Side wall 43 Ceiling 44a, 44b Rear wall 45 Front connection opening 46 Rear connection opening 47 Installation part 51 Through hole 61, 62 Air inlet 71 Connection opening 72 Air outlet 73 Installation 81 Generator 82 Power source 91 Engine (first vibration source)
92 Radiator (second vibration source)
93 Cooling fan 94 Exhaust pipe 95 Silencer 101 Floor surface U1 1st unit U2 2nd unit U3 3rd unit U4 4th unit U5 5th unit

Claims (8)

In an enclosure where the vibration source is located inside
A base plate installed on the floor and on which the vibration source is mounted,
A housing that surrounds the vibration source and is placed on the floor away from the base plate,
An air inlet portion provided on the upstream side in the air flow direction in the housing and
An air outlet provided on the downstream side of the housing in the air flow direction,
Enclosure with. The vibration source has a first vibration source and a second vibration source wider than the first vibration source, and the housing includes a first housing surrounding the first vibration source and the housing. It has a second housing that is wider than the first housing and surrounds the circumference of the second vibration source.
The enclosure according to claim 1. The base plate has a narrow portion and a wide portion, the first vibration source is mounted on the narrow portion, and the second vibration source is mounted on the wide portion.
The enclosure according to claim 2. It has the air inlet portion, and has an intake unit that is detachably connected to the upstream side in the air flow direction in the housing.
The enclosure according to any one of claims 1 to 3. It has the air outlet portion, and has an exhaust unit that is detachably connected to the downstream side in the air flow direction in the housing.
The enclosure according to any one of claims 1 to 4. A vibration isolator is provided on the base plate.
The enclosure according to any one of claims 1 to 5. The enclosure according to any one of claims 1 to 6.
A power generation unit as the vibration source arranged inside the enclosure, and
Power generation equipment equipped with. The first unit, in which the engine and generator are mounted on the first board and surrounded by the first housing,
The second unit, in which the radiator is mounted on the second base plate and the circumference is surrounded by the second housing,
A third unit arranged above the first unit and the second unit and having a silencer mounted on a third base plate,
A fourth unit having an intake duct that supplies air sucked from the air inlet to the first housing, and
A fifth unit having an exhaust duct for discharging the air of the second housing from the air outlet portion, and
With
The first unit, the second unit, the third unit, the fourth unit, and the fifth unit are power generation facilities that are detachably provided.

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