JP2012154207A - Bottom part unit of casing - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a bottom part unit of a casing capable of preventing infiltration of rain water, etc. from a drain hole into the casing and allowing sure confirmation of discharge of water, etc. from the inside of the casing.SOLUTION: This bottom part unit 30 of the casing includes: an outer bottom plate 53 forming an outside bottom part of a cogeneration case 11; and an inner bottom plate 54 overlapped with an upper side of the outer bottom plate 53 to form a double structure together with the outer bottom plate 53. In the outer bottom plate 53, an outer drain hole 72a capable of guiding water, etc. in the cogeneration case 11 to the outside of the cogeneration case 11 is provided at an upper portion P1 of the outer bottom plate 53. In the inner bottom plate 54, an inner drain hole 111 capable of guiding water, etc in the cogeneration case 11 to the outer drain hole 72a is provided at a lowest position P2 of the inner bottom plate 54.

Description

  The present invention relates to a bottom unit of a housing in which a working machine is housed inside the housing and a lower portion of the housing can be closed with a bottom plate.

Among the bottom unit of the housing, there is one in which the bottom of the side wall (circumferential wall) of the housing is covered with a bottom plate, and drain holes are provided in front, rear, left, and right portions of the bottom plate.
According to the bottom unit of the housing, water in the housing is guided to the bottom plate, and fluid such as water guided to the bottom plate can be discharged out of the housing through a plurality of drain holes (for example, (See Patent Document 1).

JP 2004-141516 A

However, since the bottom unit of the housing of Patent Document 1 is provided with drain holes at front, rear, left, and right portions of the bottom plate, the number of drain holes increases.
As described above, it is conceivable that the number of drain holes provided in the bottom plate increases so that rainwater or the like outside the casing can easily enter the casing through the drain holes.

Furthermore, the bottom unit of the housing of Patent Document 1 is provided with a plurality of drain holes in front, rear, left, and right portions of the bottom plate. Therefore, it is conceivable that fluid such as water is discharged only from the drain hole provided in the rear portion of the bottom plate.
Thus, when a fluid such as water is discharged only from the drain hole provided in the rear portion of the bottom plate, it is difficult to visually recognize (view) the discharged fluid from the front side of the housing.
For this reason, there is a possibility that a fluid such as water may be overlooked from a drain hole provided in a rear portion of the bottom plate.

  It is an object of the present invention to provide a bottom unit of a housing that can prevent rainwater and the like from entering the housing through a drain hole and can surely confirm that water has been discharged from the inside of the housing. Let it be an issue.

  According to a first aspect of the present invention, in the bottom unit of the housing that closes the lower portion of the housing in which the work machine is housed, the outer bottom portion of the housing is formed and the fluid in the housing is discharged outside the housing. The outer bottom plate in which a water drain hole that can be guided to the outside is formed and the upper bottom plate are overlapped to form a double structure together with the outer bottom plate, and the fluid in the housing can be guided to the outer water drain hole An inner bottom plate having an inner water drain hole formed therein, the inner water drain hole is provided at a lowermost portion of the inner bottom plate, and the outer water drain hole is provided at an upper portion of the outer bottom plate. It is characterized by.

  According to a second aspect of the present invention, a sound absorbing portion is interposed between the outer bottom plate and the inner bottom plate.

  According to a third aspect of the present invention, the inner drain hole and the outer drain hole are formed on the front side of the casing.

In the invention which concerns on Claim 1, the internal water drain hole was provided in the lowest site | part of the inner bottom board. Therefore, when a fluid such as water or oil of the work implement is dropped on the inner bottom plate, the dropped fluid such as water or oil can be reliably guided to the inner drain hole at the lowermost portion.
Thereby, the dropped fluid such as water or oil can be guided to the outer drain hole through the inner drain hole, and discharged from the outer drain hole to the outside of the housing.

In addition, an external water drain hole was provided in the upper part of the outer bottom plate. Therefore, even when rainwater or the like adheres to the lower surface of the outer bottom plate, it is possible to prevent the attached rainwater or the like from being guided to the outside drain hole through the lower surface.
Furthermore, by providing an external water drain hole in the upper part of the outer bottom plate, it is possible to prevent rainwater or the like from splashing on the mounting surface and entering the external water drain hole.
Thereby, it can prevent that rainwater etc. penetrate | invade in a housing | casing through an internal water drain hole from an external water drain hole.

In the invention according to claim 2, the sound absorbing portion is interposed between the outer bottom plate and the inner bottom plate.
Thereby, the noise generated from the work machine in the housing can be absorbed by the sound absorbing portion (sound absorbing material), and the noise can be prevented from being transmitted to the outside of the housing through the bottom unit.

In the invention according to claim 3, the inner drain hole and the outer drain hole are formed on the front side of the casing. Therefore, fluid such as water or oil dripped from the work machine can be discharged to the outside from the front side of the housing through the inner drain hole and the outer drain hole.
Thereby, since fluids, such as water and oil discharged | emitted from the external drain hole, can be visually observed from the front side of a housing | casing, it can confirm reliably that fluids, such as water and oil, were discharged | emitted from the inside of a housing | casing.

It is a disassembled perspective view of the cogeneration apparatus which concerns on this invention. It is a disassembled perspective view which shows the state which removed the engine from the bottom part unit of FIG. It is a disassembled perspective view which shows the bottom part unit of FIG. FIG. 4 is an enlarged view of part 4 of FIG. 3. FIG. 5 is a sectional view taken along line 5-5 of FIG. FIG. 6 is a view taken in the direction of arrow 6 in FIG. 2. FIG. 7 is a cross-sectional view taken along line 7-7 in FIG. 6. FIG. 8 is a cross-sectional view taken along line 8-8 in FIG. 6. It is a perspective view which shows the front left inner attachment part of the inner bottom board which concerns on this invention. FIG. 10 is an enlarged view of 10 parts in FIG. 8. It is a figure explaining the example which guides a fluid toward an internal drain hole with the bottom part unit concerning the present invention. It is a figure explaining the example which discharges the fluid to the exterior of a cogeneration case by the bottom unit concerning the present invention. It is a figure explaining the example which prevents the penetration | invasion of rain water into a cogeneration case with the bottom part unit which concerns on this invention.

  The best mode for carrying out the present invention will be described below with reference to the accompanying drawings. In the figure, “front”, “back”, “left”, and “right” are indicated by “Fr”, “Rr”, “L”, and “R”.

A cogeneration apparatus 10 including a bottom unit (hereinafter abbreviated as “bottom unit”) 30 of a housing according to an embodiment will be described.
As shown in FIG. 1, in the cogeneration apparatus 10, a cogeneration body (work machine) 10 </ b> A is housed in a cogeneration case (housing) 11.
The cogeneration body 10A includes an engine (prime mover) 16, a generator 18, a heat exchanger 19, a first control unit 21, a power conversion unit 22, and the like.

  Specifically, the cogeneration apparatus 10 includes a cogeneration case 11 partitioned into a power generation storage unit 12 and an electrical component storage unit 13, an engine (prime mover) 16 stored in a lower part of the power generation storage unit 12, A generator 18 provided on an upper portion of a main body (hereinafter referred to as “engine main body”) 17, a heat exchanger 19 provided on a side of the engine main body 17, and a first control stored in a lower portion in the electrical equipment storage portion 13. This is a combined heat and power supply device including a unit 21 and a power conversion unit 22 housed in the upper part of the electrical equipment housing unit 13.

The cogeneration case 11 is formed of a bottom unit 30, a front panel 31, a rear panel 32, a left side panel 33, a right side panel 34, and a roof panel 35 in a substantially rectangular shape.
The right side panel 34 has an upper panel opening 34a and a lower panel opening 34b.
An upper sub-side panel 47 is attached to the upper panel opening 34a so as to be freely opened and closed.
A lower sub-side panel 48 is attached to the lower panel opening 34b so as to be freely opened and closed.

A partition wall 36 is provided along the left side panel 33 near the left side panel 33 in the cogeneration case 11.
Further, an upper partition portion 38 is provided so as to extend from the upper end portion 36 a of the partition wall 36 to the right side panel 34.

By providing the partition wall 36 in the cogeneration case 11, the space in the cogeneration case 11 is partitioned into left and right spaces between the power generation storage unit 12 and the electrical storage unit 13.
The right power generation storage unit 12 stores (arranges) an engine 16, a generator 18, a heat exchanger 19, and the like.
The left electrical component storage unit 13 stores (arranges) a first control unit 21 and a power conversion unit (inverter unit) 22.

Furthermore, by providing the upper partition portion 38 in the cogeneration case 11, the space of the intake / exhaust portion 14 is partitioned above the power generation storage portion 12.
The intake / exhaust section 14 houses (arranges) an air cleaner device 45, a gas flow rate adjusting device, and a mixer (including a throttle valve) that constitute a part of the intake system 41 of the engine 16.
In addition, the intake / exhaust portion 14 houses (arranges) a muffler 52 that constitutes a part of the exhaust system 51 of the engine 16. An exhaust outlet 52 a communicates with the muffler 52.

  The engine 16 is a gas engine including an engine body 17, an intake system 41 provided in the engine body 17, and an exhaust system 51 provided in the engine body 17.

As shown in FIG. 2, the engine main body 17 has a mounting bracket 26 attached to the bottom of the oil tank 17 a, and the mounting bracket 26 is bolted to the intermediate bracket 27.
The intermediate bracket 27 is bolted to the bottom plate 28.
Further, the bottom plate 28 is bolted to the bottom unit 30 of the cogeneration case 11.
That is, the engine body 17 is provided in the bottom unit 30 via the mounting bracket 26, the intermediate bracket 27, and the bottom plate 28.

As shown in FIG. 1, the intake system 41 includes an air intake portion 42 provided on the rear panel 32 of the cogeneration case 11, an intake passage 43 that communicates the air intake portion 42 with an intake port 44 of the engine body 17, And an air cleaner device 45 provided in the middle of the passage 43.
In the intake passage 43, a gas flow rate adjusting device is provided on the downstream side of the air cleaner device 45, and a mixer is provided in the gas flow rate adjusting device. This mixer includes a throttle valve.

According to the intake system 41, the outside air (air) sucked from the air intake section 42 is guided to the intake passage 43, and the air guided to the intake passage 43 is guided to the air cleaner device 45.
When the air is guided to the air cleaner device 45, the guided air is purified by the air cleaner device 45. The air purified by the air cleaner device 45 is mixed with gas fuel by a mixer, and the mixed gas fuel is guided to a throttle valve.
Gas fuel that has passed through the throttle valve is introduced into the combustion chamber via the intake port 44 of the engine body 17 and the engine 16 is driven.

The generator 18 is provided on the upper part of the engine body 17, and the drive shaft of the generator 18 is coaxially connected to the crankshaft of the engine 16.
By driving the generator 18 with the engine 16, electric power (AC power) can be generated by the generator 18.

The heat exchanger 19 heats water by exchanging heat between the exhaust gas and water as the exhaust gas of the engine 16 is guided and water is guided from the outside 25.
As described above, it is possible to generate warm water using the waste heat (exhaust heat) of the engine 16 as a heat source, guide the heat of the generated warm water to the outside 25 of the cogeneration apparatus 10 and use it for heating or the like.

The first control unit 21 is disposed in the electrical equipment storage unit 13 by being provided in a substantially lower half of the partition wall 36.
The first control unit 21 is exemplified by, for example, an earth leakage breaker, but is not limited to this, and may have other engine control functions.

Incidentally, the cogeneration apparatus 10 includes a second control unit 23 on the right side of the air cleaner apparatus 45 (the space of the intake / exhaust unit 14).
The second control unit 23 is an ECU having a function of controlling the engine 16 so that the generator 18 is switched to the starter function when the engine 16 is started and the generator 18 is switched to the generator function after the engine 16 is started.
The second control unit 23 can be installed in the electrical storage unit 13 because there is no limitation in installation as long as it is a space other than the power generation storage unit 12.

The power conversion unit 22 is disposed in the electrical storage unit 13 by being provided in the upper half of the partition wall 36.
The power conversion unit 22 is an inverter unit that converts AC power generated by the generator 18 into required specification power.

The bottom unit 30 is a unit that closes the lower portion 11a of the cogeneration case 11 in which the cogeneration body 10A is housed.
As shown in FIGS. 2 and 3, the bottom unit 30 includes an outer bottom plate 53 that can be attached to the placement surface 49 (see also FIG. 1) of the cogeneration apparatus 10, and an inner bottom plate 54 that is superimposed on the outer bottom plate 53. And a sound absorbing portion 55 interposed between the inner bottom plate 54 and the outer bottom plate 53.

The outer bottom plate 53 is a substantially rectangular panel member that forms the outer bottom portion of the cogeneration case 11.
The outer bottom plate 53 includes a mounting portion 57 formed at the front, rear, left, and right end portions 53a to 53d, an outer recessed portion 58 provided in the center, and an outer portion formed near the end portion of the outer recessed portion 58. Mounting portion group 61, left and right outer positioning portions 67, 68 provided on the left and right end portions 53c, 53d side, and an external water drainage raised portion 71 formed on the front end portion of the outer recess 58 (see also FIG. 4) And have.

The mounting portion 57 is a substantially rectangular frame portion that is formed at the front, rear, left, and right end portions 53 a to 53 d and forms the lowermost portion of the outer bottom plate 53.
The mounting portion 57 is a portion that can be mounted on the mounting surface 49 on which the cogeneration apparatus 10 is installed.

The outer recess 58 includes an outer intersecting recess 73 formed so as to substantially intersect the center of the outer bottom plate 53, an outer rear recess 74 extending rearward from the vicinity of the rear right end 73d of the outer intersecting recess 73, and an outer intersection. And an outer front recess 75 extending forward from the vicinity of the intersection 73e of the recess 73.
By providing the outer bottom plate 53 with the mounting portion 57 and the outer concave portion 58, a step portion is formed on the outer bottom plate 53. Thus, by forming the step portion on the outer bottom plate 53, the rigidity of the outer bottom plate 53 can be sufficiently secured.
The outer intersecting concave portion 73, the outer rear concave portion 74, and the outer front concave portion 75 are portions recessed downward.

  The outer attachment portion group 61 includes a front left outer attachment portion 62 formed in the vicinity of the front left end portion 73a of the outer intersection recess portion 73, and a rear left outer attachment portion 63 formed in the vicinity of the rear left end portion 73b of the outer intersection recess portion 73. The front right outer mounting portion 64 formed in the vicinity of the front right end portion 73 c of the outer cross recessed portion 73 and the rear right outer mounting portion 65 formed in the vicinity of the rear right end portion 73 d of the outer cross recessed portion 73.

Hereinafter, the front left outer mounting portion 62 selected from the front left outer mounting portion 62, the rear left outer mounting portion 63, the front right outer mounting portion 64, and the rear right outer mounting portion 65 will be described in detail as a representative example. The description of the outer mounting parts 63, 64, 65 is omitted.
In addition, the same code | symbol as the front left outer attachment part 62 is attached | subjected to the structural member of the other outer attachment parts 63,64,65.

  As shown in FIG. 4, the front left outer mounting portion 62 includes a substantially frustoconical support portion 77 raised near the front left end portion 73 a of the outer intersecting recess 73, and an outer connection raised to the left side of the support portion 77. Part 81.

The support portion 77 has a support top portion 78, and an attachment hole 78 a is formed in the center of the support top portion 78.
The nut 79 is welded to the lower surface of the support top portion 78, so that the nut 79 is provided coaxially with the mounting hole 78a.
The support top portion 78 is provided at a position higher than the outer connection top portion 82 of the outer connection portion 81.

The outer connecting portion 81 has an outer connecting top portion 82, and a mounting hole 82 a is formed at the center of the outer connecting top portion 82.
The nut 83 is welded to the lower surface of the outer connection top portion 82, so that the nut 83 is provided coaxially with the mounting hole 82a.

As shown in FIGS. 3 and 4, the left outer positioning portion 67 is raised upward (inner bottom plate 54) at a portion near the front end portion 53 a among the left end 53 c side (closer) portions of the outer bottom plate 53. ing.
The right outer positioning portion 68 is raised upward (inner bottom plate 54) at a portion near the rear end portion 53 b in the vicinity of the right end portion 53 d of the outer bottom plate 53.

As shown in FIGS. 4 and 5, the outer drainage raised portion 71 is formed at the front end portion 75 a of the outer front recess 75, and has a drainage top portion 72 at the upper portion P <b> 1 of the outer bottom plate 53.
An outer water drain hole 72 a is formed at the center of the water drain top 72.
The front end 75 a of the outer front recess 75 is provided at the front center (front side) 11 b of the cogeneration case 11.
Therefore, the outside drain hole 72 a is provided in the front center 11 b of the cogeneration case 11.

By providing the drain top portion 72 in the upper portion P1, the lower surface 72b of the drain top portion 72 is provided at a position higher than the lower surface 53e of the outer bottom plate 53 by the height dimension H1.
Thereby, the external drain hole 72a is provided at a position higher than the lower surface 53e of the outer bottom plate 53 by the height dimension H1.

The outside water drain hole 72a is a hole capable of guiding fluid such as water or oil dropped from the cogeneration body 10A shown in FIG. 1 into the cogeneration case 11 to the outside of the cogeneration case 11.
The reason why the outer drain hole 72a is provided at a position higher than the lower surface 53e of the outer bottom plate 53 by the height dimension H1 will be described in detail later.

  As shown in FIG. 3 and FIG. 6, the inner bottom plate 54 has a substantially rectangular shape in plan view and is formed to have substantially the same size as the outer bottom plate, and is overlapped with the outer bottom plate 53 to form a double structure together with the outer bottom plate 53. Is a tray member.

  The inner bottom plate 54 includes a tray bottom portion 91 formed in a substantially rectangular shape in plan view, a tray peripheral wall 92 raised from a peripheral edge 91a of the tray bottom portion 91, and a protruding bottom portion provided on a left upper end 92a of the tray peripheral wall 92. 93.

  The tray bottom 91 includes a tray base 95 formed in a substantially rectangular shape in plan view, an inner recess 96 provided in the center of the tray base 95, and an inner mounting portion group 101 formed near the end of the inner recess 96. The left and right inner positioning portions 107 and 108 provided on the left and right end portions 95 a and 95 b of the tray base 95, and the inner drain hole 111 formed at the front end portion of the inner recess 96.

As shown in FIGS. 7 and 8, the tray base 95 is formed in a spherical shape with a radius R1 so as to protrude downward.
The tray base 95 is formed so as to be gradually lowered from the left end portion 95a toward the center in the width direction, and is formed to be gradually lowered from the right end portion 95b toward the center in the width direction.
Further, the tray base 95 is formed so as to gradually become lower from the rear end portion 95c toward the front end portion 95d.

Thereby, the tray base 95 is formed so that the height at the front end portion (hereinafter referred to as “center front end portion”) 95e in the front-rear direction is the lowest position at the center in the width direction.
Thus, by setting the central front end portion 95e of the tray base 95 to the lowest height position, fluid such as water or oil dropped from the cogeneration body 10A can be moved along the upper surface 95f of the tray base 95 to the central front end portion 95e. Can be suitably guided.

As shown in FIGS. 3 and 6, the inner recess 96 extends rearward from the inner intersection recess 113 formed so as to substantially intersect the center of the tray base 95 and the vicinity of the rear right end 113 d of the inner intersection recess 113. The inner rear concave portion 114 and the inner front concave portion 115 extending forward from the vicinity of the intersecting portion 113e of the inner intersecting concave portion 113 are provided.
By having the inner recess 96 in the inner bottom plate 54, a step portion is formed in the inner bottom plate 54. Thus, by forming the step portion on the inner bottom plate 54, the rigidity of the inner bottom plate 54 can be sufficiently secured.

The inner intersecting recess 113 is formed in a state of being recessed downward so as to overlap the outer intersecting recess 73 of the outer bottom plate 53.
The inner rear recess 114 is formed in a state of being recessed downward so as to overlap the outer rear recess 74 of the outer bottom plate 53.
The inner front recess 115 is formed in a state of being recessed downward so as to overlap the outer front recess 75 of the outer bottom plate 53.

The inner front recessed portion 115 extends forward from the vicinity of the intersecting portion 113e of the inner intersecting recessed portion 113, so that the front end portion 115a is positioned at the central front end portion 95e.
As described above, the front end portion 115a recessed downward is provided at the central front end portion 95e at the lowest height position, so that the front end portion 115a is lower than the lowermost portion P2 of the tray base 95 (that is, lower than the central front end portion 95e). Position).

  The inner attachment portion group 101 includes a front left inner attachment portion 102 formed in the vicinity of the front left end portion 113a of the inner intersection recess 113, and a rear left inner attachment portion 103 formed in the vicinity of the rear left end portion 113b of the inner intersection recess 113. The front right inner mounting portion 104 formed in the vicinity of the front right end portion 113c of the inner cross recessed portion 113 and the rear right inner mounting portion 105 formed at the rear right end portion 113d of the inner cross recessed portion 113 are configured.

Hereinafter, the front left inner mounting portion 102 selected from among the front left inner mounting portion 102, the rear left inner mounting portion 103, the front right inner mounting portion 104 and the rear right inner mounting portion 105 will be described in detail as a representative example. The description of the inner mounting portions 103, 104, 105 is omitted.
In addition, the same code | symbol as the front left inner attachment part 102 is attached | subjected to the structural member of the other outer attachment parts 103,104,105.

  As shown in FIG. 9, the front left inner mounting portion 102 includes a substantially frustoconical cover portion 117 raised in the vicinity of the front left end portion 113 a of the inner intersecting recess 113 and an inner connection provided on the left side of the cover portion 117. Part 121.

As shown in FIGS. 4 and 9, the cover portion 117 is provided coaxially with the support portion 77 of the front left outer mounting portion 62 provided on the outer bottom plate 53, and contacts the support top portion 78 of the support portion 77. It has a possible cover top 118.
An opening 118 a is formed in the center of the cover top portion 118.
The opening 118a is formed coaxially with the mounting hole 78a of the support portion 77 and has a larger diameter than the mounting hole 78a.

The inner connecting portion 121 is provided coaxially with the outer connecting portion 81 of the front left outer mounting portion 62 and is formed so as to be able to contact the outer connecting top portion 82 of the outer connecting portion 81.
A through hole 121 a is formed in the inner connecting portion 121. The through hole 121 a is formed coaxially with the mounting hole 82 a of the outer connecting portion 81.

According to the front left inner mounting portion 102, the cover top portion 118 abuts on the support top portion 78 and the inner connecting portion 121 is externally connected in a state where the front left inner mounting portion 102 is fitted to the front left outer mounting portion 62. It abuts on the top 82.
In this state, the mounting hole 78a of the support top 78 is exposed from the opening 118a of the cover top 118 (see also FIG. 6).
Further, the through hole 121 a of the inner connecting portion 121 is disposed coaxially with the mounting hole 82 a of the outer connecting portion 81.

As shown in FIG. 6, the left inner positioning portion 107 is raised upward at a portion near the front end portion 95 d in the left end portion 95 a of the tray base 95.
The left inner positioning portion 107 is formed so as to be fitted to the left outer positioning portion 67 of the outer bottom plate 53.
The right inner positioning portion 108 is raised upward in a portion of the right end portion 95b of the tray base 95 near the rear end portion 95c.
The right inner positioning portion 108 is formed so as to be fitted to the right outer positioning portion 68 of the outer bottom plate 53.
The inner bottom plate 54 is positioned at a normal position with respect to the outer bottom plate 53 by fitting the left inner positioning portion 107 to the left outer positioning portion 67 and fitting the right inner positioning portion 108 to the right outer positioning portion 68. Is done.

As shown in FIGS. 6 and 10, the inner drain hole 111 is formed in the front end portion 115 a of the inner front recess 115. The inner drain hole 111 is provided at the front center 11b of the cogeneration case 11 (see FIG. 1) and coaxially with the outer drain hole 72a.
The front end 115a of the inner front recess 115 is provided at the lowermost portion P2 of the inner bottom plate 54 (tray base 95).
Therefore, the inner drain hole 111 is provided in the lowermost part P2 of the inner bottom plate 54.
The lowest part P2 is the lowest part (located at the lowest position) of the tray base 95.
In addition, the inner drain hole 111 is formed with a large diameter with respect to the outer drain hole 72a.

An inner drain hole 111 is provided coaxially with respect to the outer drain hole 72a in the lowermost portion P2 of the inner bottom plate 54. Thereby, fluids, such as water and oil dripped from 10 A of cogeneration bodies, can be suitably guided to outside drain hole 72a.
In this way, by dropping the fluid such as dropped water or oil into the outer water drain hole 72a, the fluid such as water or oil guided to the outer water drain hole 72a is allowed to pass through the outer water drain hole 72a. It can be discharged to the outside 25 of the case 11.

In addition, an inner drain hole 111 and an outer drain hole 72 a are provided in the front center 11 b of the cogeneration case 11.
Therefore, fluids such as water and oil discharged from the outer drain hole 72a can be visually observed from the front center 11b of the cogeneration case 11.
Thereby, it can confirm reliably (easy) from the front side of the cogeneration case 11 that fluids, such as water and oil, were discharged | emitted from the inside of the cogeneration case 11 (namely, electric power generation accommodating part 12 (refer FIG. 1)).

  As shown in FIG. 3, the sound absorbing portion 55 is formed of a sound absorbing material such as urethane foam (urethane sponge) as an example, and is interposed between the outer bottom plate 53 and the inner bottom plate 54 (specifically, the tray base 95). Yes.

  The sound absorbing portion 55 is formed in a substantially rectangular shape, like the tray base 95, and the fitting opening portion group 131 provided in the vicinity of the four corner portions 55a to 55d and the left and right ends provided in the left and right end portions 55e and 55f. Positioning grooves 137, 138 and a drain hole escape groove 141 formed in the front end central portion 55g.

  The fitting opening group 131 includes a front left fitting opening 132 formed near the front left corner 55a of the sound absorbing portion 55 and a rear left fitting opening 133 formed near the rear left corner 55b of the sound absorbing portion 55. And a front right fitting opening 134 formed near the front right corner 55c of the sound absorbing portion 55 and a rear right fitting opening 135 formed near the rear right corner 55d of the sound absorbing portion 55. ing.

  Hereinafter, the front left fitting opening 132 selected from the front left fitting opening 132, the rear left fitting opening 133, the front right fitting opening 134, and the rear right fitting opening 135 will be described in detail as a representative example. The description of the other fitting openings 133, 134, 135 will be omitted.

  The front left fitting opening 132 is formed in a substantially darted shape so that it can be fitted to the front left outer mounting portion 62 (supporting portion 77, outer connecting portion 81) of the outer bottom plate 53.

The left positioning groove 137 is formed so as to be fitted to the left outer positioning portion 67 of the outer bottom plate 53 at a portion of the left end portion 55e of the sound absorbing portion 55 near the front left corner portion 55a.
The right positioning groove 138 is formed so as to be fitted to the right outer positioning portion 68 of the outer bottom plate 53 at a portion of the right end portion 55f of the sound absorbing portion 55 near the rear right corner portion 55d.
The sound absorbing portion 55 is positioned at a normal position with respect to the outer bottom plate 53 by fitting the left positioning groove 137 to the left outer positioning portion 67 and fitting the right positioning groove 138 to the right outer positioning portion 68. .

The drain hole escape groove 141 is provided at the front end central portion 55 g of the sound absorbing portion 55, so that it can be fitted to the outside drain raised portion 71.
By fitting the drain hole escape groove 141 to the outer water drain ridge 71, the drain hole escape groove 141 is disposed outside the outer drain hole 72 a and the inner drain hole 111.
Therefore, the outer water drain hole 72 a and the inner water drain hole 111 can be prevented from being blocked by the sound absorbing portion 55.

By interposing the sound absorbing portion 55 between the outer bottom plate 53 and the inner bottom plate 54, noise generated from the cogeneration body 10 </ b> A can be absorbed by the sound absorbing portion 55.
Thereby, it can suppress that the noise which generate | occur | produced from 10 A of cogeneration main bodies (refer FIG. 1) is transmitted to the exterior 25 of the cogeneration case 11 through the bottom unit 30. FIG.

Next, an example of assembling the bottom unit 30 will be described with reference to FIGS.
Here, in order to facilitate understanding of the assembly procedure of the bottom unit 30, the front left outer mounting portion 62 selected from the outer mounting portion group 61, the inner mounting portion group 101 and the fitting opening portion group 131, the front left inner The attachment portion 102 and the front left fitting opening 132 will be described as representative examples.
It should be noted that the outer mounting portion group 61, the inner mounting portion group 101, and other outer mounting portions, the inner mounting portion and the fitting opening portion of the fitting opening portion group 131 are also the front left outer mounting portion 62, the front left inner mounting portion 102, and the like. It is assembled in the same manner as the front left fitting opening 132.

As shown in FIGS. 2 and 3, the sound absorbing portion 55 is placed on the outer bottom plate 53 from above.
By placing the sound absorbing portion 55 on the outer bottom plate 53, the front left fitting opening 132 of the sound absorbing portion 55 is fitted to the front left outer mounting portion 62 of the outer bottom plate 53. By fitting the front left fitting opening 132 to the front left outer fitting 62, the front left outer fitting 62 projects upward from the front left fitting opening 132.
Further, the left positioning groove 137 of the sound absorbing portion 55 is fitted to the left outer positioning portion 67 of the outer bottom plate 53, and the right positioning groove 138 of the sound absorbing portion 55 is fitted to the right outer positioning portion 68 of the outer bottom plate 53. .
Therefore, the sound absorbing portion 55 is positioned at a normal position with respect to the outer bottom plate 53.

In a state where the sound absorbing portion 55 is placed on the outer bottom plate 53, the inner bottom plate 54 is placed on the sound absorbing portion 55 from above.
By placing the inner bottom plate 54 on the sound absorbing portion 55, the front left inner mounting portion 102 of the inner bottom plate 54 is fitted to the front left outer mounting portion 62 protruding from the front left fitting opening 132.
At the same time, the left inner positioning portion 107 of the inner bottom plate 54 is fitted to the left outer positioning portion 67 of the outer bottom plate 53, and the right inner positioning portion 108 of the inner bottom plate 54 is fitted to the right outer positioning portion 68 of the outer bottom plate 53. Is done.
Therefore, the inner bottom plate 54 is positioned at a normal position with respect to the outer bottom plate 53.

In this manner, the front left inner mounting portion 102 is fitted to the front left outer mounting portion 62 in a state where the inner bottom plate 54 is positioned at a normal position with respect to the outer bottom plate 53.
Therefore, the cover top portion 118 of the front left inner mounting portion 102 abuts on the support top portion 78 of the front left outer mounting portion 62 shown in FIGS. 4 and 9, and the mounting hole 78 a of the support top portion 78 is exposed from the opening 118 a of the cover top portion 118. Is done.
Further, the inner connecting portion 121 of the front left inner mounting portion 102 contacts the outer connecting top portion 82 of the front left outer mounting portion 62, and the through hole 121 a of the inner connecting portion 121 is coaxial with the mounting hole 82 a of the outer connecting portion 81. Placed on top.

As shown in FIG. 3, the bolt 144 is inserted into the through hole 121a and the mounting hole 82a from above the inner bottom plate 54.
The bolt 144 protruding from the mounting hole 82a is screwed to the nut 83 (see FIG. 4), whereby the inner bottom plate 54 is integrally attached to the outer bottom plate 53, and the assembly of the bottom unit 30 is completed.

In a state where the inner bottom plate 54 is integrally assembled with the outer bottom plate 53, a sound absorbing portion 55 is interposed between the outer bottom plate 53 and the inner bottom plate 54.
Further, the front left fitting opening 132 of the sound absorbing portion 55 is fitted to the front left outer mounting portion 62 of the outer bottom plate 53.
Accordingly, the sound absorbing portion 55 can be reliably interposed between the outer bottom plate 53 and the inner bottom plate 54 without the sound absorbing portion 55 being fastened by fastening means such as bolts and nuts, and the number of parts can be reduced. it can.

Next, an example of assembling the engine body 17 to the bottom unit 30 will be described with reference to FIGS.
After the assembly of the bottom unit 30 is completed, the bottom plate 28 is placed on each cover top portion 118 of the inner mounting portion group 101.
With the bottom plate 28 placed on each cover top portion 118, it is attached to each support top portion 78 of the outer attachment portion group 61 with bolts 146 and nuts 79 (see FIG. 4).
Thereby, the bottom plate 28 is attached to the bottom unit 30.
The engine body 17 is provided on the bottom plate 28 via an intermediate bracket 27 and a mounting bracket 26.
Therefore, the engine body 17 is assembled to the bottom unit 30 by attaching the bottom plate 28 to the bottom unit 30.

Next, an example in which the front panel 31, the rear panel 32, the left side panel 33, and the right side panel 34 are assembled to the bottom unit 30 will be described with reference to FIGS.
As shown in FIGS. 1 and 2, the bottom portion of the front panel 31, the rear panel 32, the left side panel 33, and the right side panel 34 is provided on the inner bottom plate 54.
Specifically, the lower end 31 a of the front panel 31 is provided on the front upper end 92 b of the tray peripheral wall 92 and the front upper end 93 a of the overhanging bottom portion 93.
The rear upper end 92 c of the tray peripheral wall 92 and the rear upper end 93 b of the overhanging bottom portion 93 are provided with the lower end of the rear panel 32.

Further, the lower end portion of the left side panel 33 is provided at the upper left end 93 c of the overhanging bottom portion 93.
In addition, a lower end portion 34 c of the right side panel 34 is provided at the upper right end 92 d of the tray peripheral wall 92.
A support bracket 124 is provided at the right end portion 93 d of the overhanging bottom portion 93, and a lower end portion 36 b of the partition wall 36 is provided at the support bracket 124.

Next, an example in which a fluid such as water or oil dropped from the cogeneration body 10A is discharged to the outside 25 of the cogeneration case 11 will be described with reference to FIGS.
As shown in FIGS. 11A and 11B, an internal water drain hole 111 is provided in the lowermost portion P2 of the inner bottom plate 54 (tray base 95).
The lowest part P2 is the lowest part (located at the lowest position) of the tray base 95.
Therefore, when a fluid 152 such as water or oil is dropped from the cogeneration body 10A (see FIG. 1), the dropped fluid 152 is guided along the tray base 95 toward the inner drain hole 111 as indicated by an arrow A. it can.

As shown in FIG. 12, the fluid 152 (water, oil, etc.) guided to the inner drain hole 111 can be guided to the outer drain hole 72a through the inner drain hole 111 as shown by an arrow B.
The fluid 152 guided to the outside water drain hole 72a can be discharged to the outside 25 of the cogeneration case 11 through the outside water drain hole 72a as shown by an arrow B.

Here, the inner water drain hole 111 and the outer water drain hole 72 a were formed in the front center 11 b of the cogeneration case 11.
Therefore, the fluid 152 dripped from the cogeneration main body 10A (see FIG. 1) can be discharged to the outside 25 from the front center 11b of the cogeneration case 11 through the inner drain hole 111 and the outer drain hole 72a.

Thereby, the fluid 152 discharged | emitted from the outside drain hole 72a can be visually observed from the front center 11b of the cogeneration case 11. FIG.
Therefore, it can be confirmed with certainty that the fluid 152 has been discharged from the inside of the cogeneration case 11 (specifically, the power generation housing 12).

Next, an example of preventing rainwater 154 and the like from entering the cogeneration case 11 from the outside 25 of the cogeneration case 11 will be described with reference to FIG.
As shown in FIG. 13, by providing the outer water drainage raised portion 71 on the outer bottom plate 53, the drainage top portion 72 of the outer water drainage raised portion 71 is provided in the upper portion P1.
By providing the drainage top portion 72 in the upper portion P1, the outer drainage hole 72a of the drainage top portion 72 is provided at a position higher than the lower surface 53e of the outer bottom plate 53 by the height dimension H1.
Therefore, even when rainwater 154 or the like adheres to the lower surface 53e of the outer bottom plate 53, the attached rainwater 154 or the like can be prevented from being guided to the outer water drain hole 72a via the lower surface 53e.

Further, by providing the external water drain hole 72a in the upper portion P1 of the outer bottom plate 53, even if the rain water 154 rebounds as shown by the arrow C on the mounting surface 49, the rebound rain water 154 or the like enters the external water drain hole 72a. Intrusion can be prevented.
Thereby, it is possible to prevent rainwater 154 and the like from entering the cogeneration case 11 from the outer water drain hole 72a through the inner water drain hole 111.

In addition, the outer drain hole 72 a is formed with a small diameter with respect to the inner drain hole 111.
Accordingly, it is possible to more suitably prevent rainwater 154 and the like from entering the cogeneration case 11 through the external water drain hole 72a.

Note that the bottom unit of the casing according to the present invention is not limited to the above-described embodiments, and can be changed or improved as appropriate.
For example, in the above-described embodiment, the gas engine 16 is exemplified as the prime mover. However, the present invention is not limited thereto, and other engines such as a gasoline engine may be used.

  Moreover, although the said Example demonstrated the example which accommodated the cogeneration main body (work machine) 10A in the cogeneration case 11, and employ | adopted the bottom part unit 30 at the bottom part of the cogeneration case 11, it is not restricted to this, Other work It is also possible to employ the bottom unit 30 at the bottom of a housing that houses a machine (for example, a generator or a pump).

  Further, the cogeneration apparatus 10, the cogeneration body 10 </ b> A, the cogeneration case 11, the bottom unit 30 of the housing, the outer bottom plate 53, the inner bottom plate 54, the sound absorbing portion 55, the outer water drain hole 72 a and the inner water drain shown in the above embodiment. The shape and configuration of the holes 111 and the like are not limited to those illustrated, and can be changed as appropriate.

  INDUSTRIAL APPLICABILITY The present invention is suitable for application to a cogeneration apparatus in which a working machine is housed in a housing and a bottom unit of the housing that can close a lower portion of the housing with a bottom plate.

  DESCRIPTION OF SYMBOLS 10 ... Cogeneration apparatus, 10A ... Cogeneration main body (work machine), 11 ... Cogeneration case (casing), 11a ... Lower part of cogeneration case, 11b ... Front center of cogeneration case (front side), 25 ... Outside of cogeneration case, DESCRIPTION OF SYMBOLS 30 ... Bottom unit of housing, 53 ... Outer bottom plate, 54 ... Inner bottom plate, 55 ... Sound absorbing part, 72a ... Outer water drain hole, 111 ... Inner water drain hole, 152 ... Water and oil (fluid), P1 ... Upper Site, P2 ... bottom site.

Claims (3)

In the bottom unit of the housing that closes the lower part of the housing in which the work machine is housed,
An outer bottom plate that forms an outer bottom portion of the housing and is formed with an outside drain hole capable of guiding the fluid in the housing to the outside of the housing;
An inner bottom plate that is superimposed above the outer bottom plate to form a double structure together with the outer bottom plate, and has an inner water drain hole capable of guiding fluid in the housing to the outer water drain hole;
With
The inner drain hole is provided in the lowermost portion of the inner bottom plate,
The bottom unit of the casing, wherein the outer drain hole is provided in an upper portion of the outer bottom plate.   The bottom unit of the housing according to claim 1, wherein a sound absorbing portion is interposed between the outer bottom plate and the inner bottom plate.   The bottom unit of the casing according to claim 1, wherein the inner drain hole and the outer drain hole are formed on a front side of the casing.

Images