JP5343151B2 - Rainwater infiltration prevention structure - Google Patents

Description

  The present invention relates to a rainwater intrusion prevention structure for an engine-driven work machine, and relates to a rainwater intrusion prevention structure for preventing rainwater from flowing into a leakage storage part.

  As a base for an engine-driven work machine, a technique related to a transfer stand is disclosed in Patent Document 1, for example. A recess is formed in the transportation platform disclosed in Patent Document 1, and a large fuel tank is installed in the recess. Furthermore, the bottom part has a water-tight structure, and leaks of the engine-driven work machine are shielded to form a leak storage part, thereby preventing leakage of leaks to the outside.

Japanese Patent No. 3300933

However, for example, the technique disclosed in Patent Document 1 does not consider the countermeasure against rainwater that enters from the outside into the housing of the engine-driven work machine.
An engine-driven work machine draws external air with an engine fan and blows the air to a heat exchanger such as a radiator to produce cooling air. For example, even if the weather suddenly changes and it rains, The engine-driven work machine cannot be stopped until cooling in the exchanger is completed.
When the operation of the engine-driven work machine is continued in the rainy condition, rainwater is released from openings formed in the casing, such as air exhaust vents, and gaps formed in the casing opening / closing section and sheet metal mating surfaces. May penetrate.

In the technology disclosed in Patent Document 1, a region having a capacity that exceeds the total amount of leaked material of the engine-driven work machine such as coolant, engine lubricating oil, and operating lubricating oil is secured as the leaked material storage unit. However, as described above, when rainwater enters the inside of the housing from the opening or gap formed in the housing and flows into the leakage storage section, it mixes with the leakage from the engine-driven work machine. The total amount of spillage exceeds the capacity of the spillage reservoir, and spillage overflows from the spillage reservoir.
And the leaking substance overflowing from the leaking substance storage part may leak from the engine-driven working machine and affect the external environment.

  Then, this invention makes it a subject to provide the rainwater permeation prevention structure of an engine drive type working machine which prevents inflow of rainwater to a leaking substance storage part.

In order to solve the above problems, the present invention accommodates an engine, a fuel tank for storing fuel to be supplied to the engine, and a work implement main body driven by the engine, and an exhaust port and a hook member are arranged. An engine-driven working machine rainwater intrusion prevention structure having a housing formed in a ceiling, and a recessed groove to be provided, and a recessed portion in which a fuel filler opening for injecting fuel into the fuel tank is formed, wherein the recessed portion An opening / closing lid that can be closed so as to be covered is provided, and the recess has a box-shaped filler port member having a filler opening portion opened at a bottom portion having an area larger than an opening area of the filler port. The oil supply opening is communicated with the oil supply opening so as to communicate with the oil supply opening, and a protrusion is formed around the oil supply opening, and the groove extends from one end of the ceiling to the other end. The exhaust port and the recess are formed by It was being formed at positions sandwiching the groove with each other.

  According to the present invention, rainwater staying in the recess of the oil filler opening formed in the ceiling portion of the housing can be drained through the recessed groove in which the hook member is disposed without reaching the exhaust outlet.

  Further, the present invention is characterized in that the concave portion communicates with the concave groove.

  According to this invention which concerns, the water of the recessed part of a fuel filler opening can be actively drained to a ditch | groove.

  Further, the present invention is characterized in that the concave groove is formed deeper than the concave portion.

  According to this invention which concerns, the rain water which retains in a recessed part can be drained to a recessed groove efficiently.

According to the rainwater intrusion prevention structure according to the present invention, the air exhaust port formed in the ceiling portion of the housing and the concave portion in which the oil supply port is opened are positioned so as to sandwich the concave groove that crosses from one end of the ceiling portion to the other end. Formed. According to this configuration, even if rainwater staying in the recess overflows from the recess, the overflowing rainwater flows into the recessed groove and does not reach the exhaust port. Therefore, the rainwater overflowing from the concave portion does not enter the inside of the housing from the air outlet, and the rainwater does not flow into the leakage storage portion formed inside the housing.
Furthermore, a conventionally formed groove can be used for attaching the hook member, and it is not necessary to newly form a groove for preventing rainwater intrusion.

In the rainwater intrusion prevention structure according to the present invention, the recess formed in the ceiling portion of the housing and having the oil filler opening is communicated with a recess groove formed across from one end of the ceiling portion to the other end. Furthermore, the concave groove was formed deeper than the concave portion where the oil filler opening was opened. With this configuration, rainwater that has entered the recess where the oil filler opening opens does not stay and flows into the recess, and is drained through the recess without entering the interior of the housing.
Therefore, rainwater does not flow into the leakage storage part formed inside the housing.

  As described above, the present invention can provide a rainwater intrusion prevention structure for an engine-driven working machine that prevents the inflow of rainwater into the leakage storage part.

It is a figure showing an engine drive type working machine provided with an environment correspondence type base concerning this embodiment. (A) is a perspective view of an environment-responsive base, and (b) is an X1-X1 cross-sectional view in (a) of FIG. It is X2-X2 sectional drawing in Fig.2 (a). It is a figure which shows the housing | casing of an engine drive type working machine. It is a figure which shows the front side of an environment corresponding type | mold base. It is a schematic diagram which shows the flow of the water in the front side of an environment corresponding type | mold base. It is a figure which shows the back side of an environment corresponding type | mold base. It is a figure which shows an oil supply part. It is a figure which shows a latching | locking part. It is X4-X4 sectional drawing in FIG.

  Hereinafter, the best mode for carrying out the present invention will be described in detail with reference to the drawings as appropriate.

FIG. 1 is a diagram showing an arrangement of main devices of an engine-driven work machine having an environment-responsive base according to the present embodiment, omitting a housing. As shown in FIG. 1, in an engine-driven work machine 1 according to the present embodiment, an engine 1 a and a work machine main body 1 c are fixed to an environment-responsive base 2. The output shaft 1d that outputs the rotation of the engine 1a and the work machine main body 1c are connected, and the work machine main body 1c is driven by the rotation of the engine 1a.
The work machine body 1c is, for example, a generator.

The fuel tank 1b is connected to the engine 1a and supplies fuel such as light oil to the engine 1a. In addition, although not shown, a control device for controlling the driving of the engine 1a and the work machine main body 1c, a device for managing fuel supply to the engine 1a, an engine cooling device (hereinafter collectively referred to as auxiliary machinery), and the like Is fixed to the environmentally friendly base 2.
In the following description, the engine-driven work machine 1 has the side on which the engine 1a is arranged, that is, one side as the front Fr, and the side on which the work machine main body 1c is arranged, that is, the other side on the back. Let Rr.

2A and 2B are diagrams showing an environment-responsive base, in which FIG. 2A is a perspective view of the environment-responsive base, and FIG. 2B is a cross-sectional view taken along line X1-X1 in FIG.
Here, in the environment-friendly base 2 as well, the side on which the engine 1a (see FIG. 1) is arranged is the front Fr, and the work machine main body 1c (see FIG. 1), like the engine-driven work machine 1 (see FIG. 1). The side on which is arranged is defined as a rear surface Rr. Further, the left surface Le and the right surface Ri are set as viewed from the front Fr side. Further, the right surface Ri and the left surface Le may be collectively referred to as both side surfaces. The length between both side surfaces is referred to as the width, and the length from the front surface Fr to the back surface Rr is referred to as the depth.

  As shown in FIG. 2 (a), the environmentally friendly base 2 is a box-shaped member that is open at the top, and bends and raises both ends of a rectangular member, for example, a sheet metal substantially vertically, A back surface portion 33 is formed, and a bottom surface portion 31 (floor plate) is formed between the front surface portion 32 and the back surface portion 33. Further, the side surface portions 34 and 34 are fixed to the end portion on the left surface Le side and the end portion on the right surface Ri side of the bottom surface portion 31, the front surface portion 32, and the back surface portion 33 to form a box-like shape having an open top surface. To do. Here, the front part 32, the back part 33, and the side parts 34, 34 form a frame member.

The side surface portion 34 is a member having a substantially U-shaped cross section, for example. Then, the bottom surface portion 31 of the environmentally friendly base 2 is between the two side surface portions 34, and the side surface portion 34 has a bottom surface portion 31, a front surface portion 32, and a back surface portion 33 so that the U-shaped opening faces outward. The environmentally friendly base 2 having an opening having a water-tight structure is configured by being fixed to the end of (see FIG. 2A) by continuous welding or the like. Thus, since the opening has a watertight structure, the leakage storage part 3a can be formed in the opening of the environment-friendly base 2. And it can prevent that a liquid leaked substance leaks outside the environment corresponding type | mold base 2 by storing a leaked substance in the leaked substance storage part 3a.
In addition, it is good also as a structure which raises the intensity | strength of the side part 34 by raising both ends of the side part 34, forming a shallow box shape.

The upper end portion of the front portion 32 is bent toward the outside of the environment-friendly base 2 to form an upper surface portion 32 a that is substantially parallel to the bottom surface portion 31. Similarly, the upper end portion of the back surface portion 33 is also bent toward the outside of the environment-friendly base 2 to form an upper surface portion 33a. Moreover, in the side part 34, the upper surface part 34a is formed in the U-shaped upper end side.
In the present embodiment, the upper surface portion 32 a of the front surface portion 32 and the upper surface portion 33 a of the back surface portion 33 are formed lower in the vertical direction than the upper surface portion 34 a of the side surface portion 34.

The environment-responsive base 2 includes an engine fixing base 22 for fixing the engine 1a (see FIG. 1) and a work machine main body fixing base 23 for fixing the work machine main body 1c (see FIG. 1).
The engine fixing pedestal 22 has a U-shaped opening formed between two side surfaces 34, 34, for example, by placing a U-shaped bar in a cross section in parallel with the front surface 32 and the back surface 33. It is formed fixed downward. The engine 1a is mounted on an engine fixing base 22, and is fixed by an appropriate means such as fixing with a bolt and a nut (not shown) through vibration-proof rubber, for example.

  The work implement main body fixing pedestal 23 is provided with, for example, a U-shaped cross section placed horizontally between the two side surfaces 34, 34 so as to be parallel to the engine fixing pedestal 22, and a U-shaped opening. It is formed to be fixed downward. The work machine main body 1c (see FIG. 1) is placed on the work machine main body fixing base 23 and fixed by appropriate means such as fixing with bolts and nuts (not shown) through vibration-proof rubber, for example.

The method of fixing the engine fixing base 22 and the work machine main body fixing base 23 is not limited. For example, as shown in FIG. 2A, a pedestal 34b protrudes from the side surface 34 toward the inside of the environmentally friendly base 2, and the engine fixing pedestal 22 and the work implement main body fixing pedestal 23 are formed on the pedestal 34b. May be fixed by screwing or welding.
Alternatively, the engine fixing base 22 and the work machine main body fixing base 23 may be directly fixed to the side surface portion 34 by welding or screwing.

  Furthermore, the environment-compatible base 2 is provided with a guide base 37. The guide base 37 is installed between the two side surfaces 34, 34 so as to be substantially parallel to the engine fixing base 22, and is provided on the front side of the engine fixing base 22.

  As shown in FIG. 2B, the cross-sectional shape of the guide base 37 is such that both ends of the flat portion 37b are bent substantially vertically and bent to the opposite side to form upright portions 37a and 37c. The guide base 37 is an upright bent downward so that the flat surface portion 37b is substantially parallel to the bottom surface portion 31 and the flat surface portion 37b is substantially the same height as the upper surface portion 34a of the side surface portion 34. The portion 37c is provided on the front Fr side.

  That is, the upright portion 37 a bent upward is provided to protrude upward from the upper surface portion 34 a of the side surface portion 34. Further, the guide base 37 is provided in the environment-friendly base 2 so that the lower end side of the standing part 37c bent downward is higher than the upper surface part 32a of the front part 32.

  The left and right end portions of the flat surface portion 37b and the upright portion 37c of the guide base 37 are sandwiched between the two side surface portions 34 and 34 and fixed by, for example, continuous welding. In this way, a watertight structure is formed between the guide base 37 and the side surface portion 34 by continuously welding both end portions of the guide base 37 in the longitudinal direction to the side surface portion 34.

Further, as shown in FIG. 2B, a drain cock 35 is provided below the front surface portion 32 (on the bottom surface portion 31 side) of the environment-responsive base 2.
FIG. 3 is a cross-sectional view taken along the line X2-X2 in FIG. Although the structure of the drain cock 35 is not limited, for example, as shown in FIG. 3, there is a structure in which the discharge pipe 35 c is opened and closed by the rotation of the valve body 35 b provided in the cylindrical discharge pipe 35 c that penetrates the front portion 32. Conceivable. If the valve body 35b is configured to rotate integrally with the cock lever 35a provided outside the discharge pipe 35c, the discharge pipe 35c can be opened and closed by manually operating the cock lever 35a, for example. And by opening the discharge pipe 35c, the leakage storage part 3a and the outside are opened, and the leakage stored in the leakage storage part 3a can be discharged to the outside of the environment-responsive base 2.

  In addition, the structure provided with the saucer 32b below the drain cock 35 may be sufficient. The tray 32b is, for example, a member having a substantially L-shaped cross section fixed to the bottom surface portion 31 such that the side surface portion 34 forms one side wall, and its end portion is closer to the front portion 32 than the end portion of the drain cock 35. Protruding structure. By having the receiving tray 32b having such a structure, even if there is a leaked material leaking from the drain cock 35, it is possible to prevent the surrounding environment where the environment-responsive base 2 is installed from being received by the receiving tray 32b.

  Further, as shown in FIG. 3, the drain cock 35 has at least the lowest part inside the discharge pipe 35 c at a position equivalent to the top surface of the bottom surface portion 31 (see FIG. 2A) or the top surface of the bottom surface portion 31. You may fix so that it may become below. By fixing in this way, it is possible to prevent leakage from staying at the boundary between the bottom surface portion 31 and the drain cock 35, and it is possible to completely discharge the leakage stored in the leakage storage portion 3a.

Conventionally, the base to which the engine 1a (see FIG. 1) and the work machine main body 1c (see FIG. 1) are fixed and the base on which the leakage storage part 3a is formed are formed as separate members, and the base is used as the base. The engine-driven work machine 1 (see FIG. 1) may be configured by being fixed so as to be placed.
The environment-responsive base 2 according to the present embodiment has a function equivalent to that in the case where a conventional base and base are configured integrally.

  FIG. 4 is a diagram illustrating a housing of the engine-driven working machine. The engine-driven work machine 1 (see FIG. 1) according to the present embodiment includes a front frame 40, a rear frame 41, a left frame 42, a right frame 43, and an upper frame 44 that are fixed to the environment-friendly base 2. The body 10 is configured.

As shown in FIG. 4, a front frame 40 is disposed on the front surface Fr side of the environment-responsive base 2, and a rear frame 41 is disposed on the rear surface Rr side.
A left frame 42 and a right frame 43 are disposed on the left and right sides Le and Ri of the front frame 40 and the rear frame 41, respectively.
Further, an upper frame 44 is provided so as to cover the front frame 40, the rear frame 41, the left frame 42, and the right frame 43 from above.

  The front frame 40, the rear frame 41, the left frame 42, the right frame 43, and the upper frame 44 are connected to each other to form the housing 10 and are fixed to the environment-friendly base 2.

  At this time, a gap is formed in the connecting portion of the front frame 40, the rear frame 41, the left frame 42, the right frame 43, and the upper frame 44, and rainwater may enter the inside of the housing 10.

The upper frame 44 has an air exhaust opening 44a at a position corresponding to the upper side of the front frame 40, and an opening is formed above the front frame 40 formed in a hollow rectangular tube shape.
Since the air exhaust port 44 a is opened upward, rainwater enters the hollow portion of the front frame 40 from the air exhaust port 44 a and enters the inside of the housing 10 through the hollow portion of the front frame 40.

As described above, the rainwater entering from the opening formed in the housing 10 such as the air outlet 44a and the gap formed in the connecting portion is discharged to the outside of the housing 10, so A drainage guide 401 is provided on the Fr side and the back surface Rr side.
The drainage guide 401 has a function of preventing rainwater from entering the leakage storage part 3a (see FIG. 2A) of the environment-responsive base 2.

  The upper frame 44 is provided with a groove 440d for disposing a hook member (not shown), a connecting member 440e spanning the upper surface of the groove 440d, and an oil supply portion 440, which will be described in detail later.

FIG. 5 is a diagram showing the front side of the environment-friendly base.
As shown in FIG. 5, the drainage guide 401 is a shallow box-shaped member having a substantially rectangular planar shape, and the bottom portion 401d is formed to have a substantially rectangular planar shape.
The width of the bottom portion 401d in the left-right direction is formed to be equal to the distance between the two side surfaces 34, 34 (see FIG. 2A) of the environment-responsive base 2, and one of the end portions in the width direction rises to form a side wall. 401a is formed.

The bottom portion 401d is bent and raised at a minute angle in the same direction as the side wall 401a from a position separated from the side wall 401a by a predetermined length to form an inclined portion 401d2. A portion between the side wall 401a and the starting point of the inclined portion 401d2 is referred to as a flat portion 401d1.
Furthermore, at least one drain outlet 401f is formed at the end of the side wall 401a on the flat portion 401d1 side.

Both ends of the inclined portion 401d2 of the bottom portion 401d stand up to form side walls 401c and 401c. Further, the end portion of the bottom portion 401d facing the side wall 401a rises to form the side wall 401b.
Thus, the drainage guide 401 is formed, and notches 401e and 401e are provided between the side wall 401a and the side walls 401c and 401c.

As shown in FIG. 5, the drainage guide 401 is provided such that the side wall 401 a is disposed on the front Fr side, and the flat portion 401 d 1 is placed on the upper surface portion 32 a (see FIG. 2A) of the front portion 32. The flat portion 401d1 is fixed to the upper surface portion 32a by a screw member or the like (not shown).
Alternatively, the flat portion 401d1 may be fixed to the upper surface portion 32a by welding or the like.

Since the width of the bottom portion 401d of the drainage guide 401 is formed to be equal to the interval between the side surface portions 34, 34, the side walls 401c, 401c are in contact with the side surface portions 34, 34 and are fastened by a fastening member such as a bolt B and a nut (not shown). It is fixed to the side portions 34, 34.
Alternatively, the side walls 401c and 401c may be fixed to the side surfaces 34 and 34 by welding or the like.

Further, the side wall 401b of the drainage guide 401 overlaps with the standing portion 37c of the guide base 37 from the rear surface Rr side, and the side wall 401b is fixed to the standing portion 37c with a fastening member such as a bolt B and a nut (not shown).
Alternatively, the side wall 401b may be fixed to the standing portion 37c by welding or the like.

Further, as described above, the front frame 40 is disposed on the front surface Fr side of the environment-responsive base 2.
As shown in FIG. 5, the front frame 40 is a hollow rectangular tube-like member that penetrates vertically, and the width W <b> 1 is the width of the environment-friendly base 2 (upper surface portions 34 a, 34 a of the side surface portions 34, 34). The depth D1 is substantially equal to the length from the front end portion of the side surface portion 34 to the standing portion 37a of the guide base 37.

The front frame 40 is placed on a plane formed by the upper surface portions 34 a and 34 a of the two side surface portions 34 and 34 and the flat surface portion 37 b of the guide base 37, and is fixed to the environment-friendly base 2.
That is, the guide base 37 and the drainage guide 401 are disposed below the front frame 40. Further, as shown in FIG. 4, the upper frame 44 is a drainage member because an exhaust port 44 a is opened at a position corresponding to the upper side of the front frame 40 and an opening is formed above the front frame 40. The guide base 37 and the drainage guide 401 are disposed below the opening.

  The fixing method of the front frame 40 is not limited. For example, the fixing portion 40a is formed by bending the lower end portion in the depth direction inward, and the fixing portion 40a is placed on the upper surface portion 34a of the side surface portion 34. The fixing portion 40a and the upper surface portion 34a may be fixed with a fastening member such as a bolt (not shown).

The front frame 40 includes an engine 1a that is fixed to the environment-responsive base 2 and an engine fan F that cools the work machine main body 1c (see FIG. 1), and the hollow portion forms an exhaust passage.
Therefore, the upper end portion of the front frame 40 cannot be completely shielded, and as shown in FIG. 4, an air exhaust port 44 a is opened in the upper frame 44 above the front frame 40. As a result, for example, rainwater may enter the hollow portion of the front frame 40 from the air outlet 44 a of the upper frame 44 and enter the inside of the housing 10 (see FIG. 4) through the hollow portion of the front frame 40. .

  FIG. 6 is a schematic diagram showing the flow of water on the front side of the environment-responsive base. Referring to FIG. 6, on the front side Fr side of engine-driven work machine 1 (see FIG. 1), rainwater or the like entering the inside of casing 10 (see FIG. 4) through the hollow portion of front frame 40 The flow of the water Wa will be described.

As described above, the front frame 40 is a member that is hollow in the vertical direction, and water Wa such as rainwater passes through the hollow portion of the front frame 40 from the air outlet 44a of the upper frame 44 (see FIG. 4). 10 (see FIG. 4).
As shown in FIG. 6, since the guide base 37 and the drainage guide 401 are disposed below the front frame 40, water Wa such as rainwater that has entered the inside of the housing from the hollow portion of the front frame 40 is The flat surface portion 37b of the guide base 37 or the bottom portion 401d (flat portion 401d1, inclined portion 401d2) of the drainage guide 401 is received.
That is, the flat surface portion 37b of the guide base 37 and the bottom portion 401d (flat portion 401d1, inclined portion 401d2) of the drainage guide 401 serve as a water receiving portion.

As described above, since the end portion of the guide base 37 forms a watertight structure with the side surface portion 34 by continuous welding or the like, the water Wa received by the flat surface portion 37b is between the guide base 37 and the side surface portion 34. Does not penetrate.
Then, the water Wa flowing into the drainage guide 401 from the flat portion 37b of the guide base 37 and the water Wa received by the inclined portion 401d2 flow through the inclined portion 401d2 and reach the flat portion 401d1. Since side walls 401c and 401c are formed at both ends of the inclined portion 401d2, the water Wa flowing through the inclined portion 401d2 does not enter between the both ends of the inclined portion 401d2 and the side surface portion 34.

  And the water Wa which reached | attained the flat part 401d1 becomes drainage from the drain outlet 401f formed in the side wall 401a, and is discharged | emitted by the front Fr side.

  As described above, the water Wa such as rainwater received by the flat surface portion 37b of the guide base 37, the inclined portion 401d2 of the drainage guide 401, and the flat portion 401d1 becomes drainage from the drainage port 401f to the outside of the environment-responsive base 2. Are not discharged and do not flow into the leakage storage part 3a.

  In addition, when the notch part 401e (refer FIG. 5) is formed in the back surface Rr side from the front part 32 (refer FIG. 5), water flows into back surface Rr, ie, the leakage storage part 3a, from the front part 32. The notch 401e is preferably not formed on the rear surface Rr side from the front surface portion 32.

  With such a structure, it is possible to prevent the water Wa such as rainwater that has entered the inside of the housing from flowing into the leakage storage part 3a on the front surface Fr of the environment-responsive base 2 (see FIG. 4).

  As described above, the water Wa entering the front Fr side from the flat portion 37b of the guide base 37 is received by the flat portion 37b of the guide base 37, the flat portion 401d1 and the inclined portion 401d2 of the drainage guide 401, and is environmentally friendly. Since water is discharged without flowing into the leakage storage part 3a of the base 2, water Wa such as rainwater entering from the upper end of the front frame 40 is discharged without flowing into the leakage storage part 3a. Therefore, the guide base 37 and the drainage guide 401 are drainage members.

Further, as shown in FIG. 4, a rear frame 41 is fixed to the back surface Rr side of the environment-responsive base 2.
The rear frame 41 is made of, for example, a substantially U-shaped member, and is erected and fixed so that the U-shaped opening side is on the front Fr side. The height of the rear frame 41 is equal to that of the front frame 40. The

  And as shown in FIG. 4, the drainage guide 401 is fixed to the back surface Rr side of the environment-responsive base 2 according to the present embodiment.

  The structure of the drainage guide 401 on the back surface Rr side of the environmentally friendly base 2 is substantially the same as the front Fr side except that the side wall 401b (see FIG. 5) is not fixed to the standing portion 37c (see FIG. 5) of the guide base 37. The structure is equivalent, and detailed description is omitted.

FIG. 7 is a diagram showing the back side of the environment-responsive base.
As shown in FIG. 7, the width W <b> 1 of the rear frame 41 is formed to be substantially equal to the width of the environment-responsive base 2. Then, the U-shaped side surface is bent inward at the lower end side to form the fixing portion 41a.
The rear frame 41 is disposed such that the fixing portion 41a is placed on the upper surface portion 34a of the side surface portion 34, and is fixed by fastening the fixing portion 41a and the upper surface portion 34a with, for example, a bolt B and a nut (not shown).

Moreover, as shown in FIG. 7, the drainage guide 401 provided on the back surface Rr side of the environment-responsive base 2 may be formed by bending the upper end portion of the side wall 401a to the bottom portion 401d side to form the upper surface portion 401a1. And the lower end part of the bottom part 41b of the U-shaped opening of the rear frame 41 is bent inward to form the fixing part 41b1, and the fixing part 41b1 is placed on the upper surface part 401a1, and the fixing part 41b1 and the upper surface part 401a1. For example, the bolt B and the nut (not shown) may be fastened and fixed.
Thus, the rear frame 41 can be reliably fixed to the environment-friendly base 2 by fixing the fixing portion 41b1 and the upper surface portion 401a1.

As shown in FIG. 7, when the rear frame 41 is fixed to the environment-compatible base 2, the rear frame 41 is provided entirely above the drainage guide 401.
That is, the drainage guide 401, which is a drainage member, includes the rear frame 41, and other members (for example, the upper frame 44 (see FIG. 4) and the left frame 42 (see FIG. 4) that constitute the housing 10 (see FIG. 4). The right frame 43 (see FIG. 4)) is disposed below a gap (not shown) formed at the connecting portion. Then, all of the water Wa such as rainwater entering from the gap formed in the connecting portion of the housing 10 is received by the drainage guide 401 and discharged from the drainage port 401f to the back surface Rr side as drainage. With this structure, it is possible to prevent water Wa such as rainwater that enters the inside of the housing 10 from the gap formed in the connecting portion of the housing 10 from flowing into the leakage storage portion 3a.

The left frame 42 shown in FIG. 4 is a plate-like member, for example, and is provided so as to form the side surface of the left surface Le of the engine-driven working machine 1 to which the front frame 40 and the rear frame 41 are fixed.
For example, the left frame 42 is fixed to the front frame 40 with an end portion on the front Fr side and a fastening member such as a bolt and a nut (not shown), and an end portion on the rear Rr side is attached to the rear frame 41 and a bolt (not shown). It is fixed with a fastening member such as a nut.

Further, as shown in FIG. 4, an upper frame 44 is provided on the upper part of the engine-driven work machine 1.
The upper frame 44 is provided so as to face the environment-friendly base 2 so as to cover the front frame 40, the rear frame 41, and the right frame 42 from above, and the upper frame 44 of the casing 10 of the engine-driven work machine 1 (see FIG. 1). Form the ceiling.

  As shown in FIG. 4, the upper frame 44 is made of a member having a U-shaped cross section, for example, and the length is substantially equal to the length from the front Fr side to the back surface Rr side of the engine-driven work machine 1. The formed width W1 is substantially equal to the width W1 of the front frame 40 and the rear frame 41.

  The upper frame 44 has a U-shaped opening facing downward so that the front frame 40 and the rear frame 41 fit into the U-shaped opening. For example, a bolt B and a fastening member such as a nut (not shown) Thus, the front frame 40 and the rear frame 41 are fixed.

  An air exhaust port 44a is opened at a position corresponding to the upper side of the front frame 40 on the front surface Fr side of the upper frame 44, and the hollow portion of the front frame 40 is ventilated by the engine fan F (see FIG. 5) provided in the front frame 40. Exhaust air.

Further, the upper frame 44 is formed with a concave groove 440d so as to cross from the right surface Ri side to the left surface Le side, for example.
A connecting member 440e made of steel, for example, is stretched over the upper surface of the recessed groove 440d to be reinforced.
A hook member (not shown) is disposed in the concave groove 440d, and functions as a hook for hanging a rope, for example, when the engine-driven work machine 1 is transported.

Further, an oil supply portion 440 is formed at the approximate center in the longitudinal direction of the upper frame 44, in which an oil supply port 440b for injecting fuel into the fuel tank 1b (see FIG. 1) is opened.
FIG. 8 is a diagram illustrating the oil supply section.
As shown in FIG. 8, the oil filler 440 is formed by fixing an oil filler member 440 c to a recess 440 a formed by the upper frame 44 being recessed in a substantially rectangular shape.
The recess 440a is formed with an oil supply port 440b penetrating the upper frame 44, and the oil supply port member 440c is fixed to the recess 440a so as to cover the oil supply port 440b from above.

The oil filler member 440c is a shallow box-shaped member, and the area of the bottom thereof is larger than the opening area of the oil filler port 440b that opens into the recess 440a of the upper frame 44. Furthermore, a fuel supply opening 440c1 opens at the bottom of the fuel supply port member 440c.
The fuel filler member 440c is fixed to the recess 440a so that the fuel filler opening 440c1 and the fuel filler 440b of the recess 440a communicate with each other.
The method of fixing the fuel filler member 440c to the recess 440a is, for example, by continuously welding the periphery of the fuel filler member 440c to form a watertight structure between the fuel filler member 440c and the upper frame 44.
For example, the fuel supply opening 440c1 communicates with a fuel supply port of the fuel tank 1b (see FIG. 1) via a pipe line (not shown).
Further, for example, the depth of the fuel filler member 440c may be formed substantially equal to the depth of the recess 440a. That is, the height of the side wall forming the shallow box shape of the fuel filler member 440c is set to be substantially equal to the partition wall 440f described later.

The concave portion 440a of the oil supply unit 440 according to the present embodiment is formed adjacent to the concave groove 440d, and the concave groove 440d and the concave portion 440a are partitioned by a partition wall 440f. The concave portion 440a is formed shallower than the concave groove 440d, and at least one drain port 440g is formed in the partition wall 440f so as to communicate the concave portion 440a and the concave groove 440d.
In addition, you may comprise so that the recessed part 440a and the recessed groove 440d may connect without forming the partition 440f.

  Further, as shown in FIG. 4, in the present embodiment, the air exhaust port 44 a that opens to the upper frame 44 and the recess 440 a of the oil supply unit 440 are formed at a position sandwiching the recess 440 d.

As shown in FIG. 8, the oil supply portion 440 formed in the upper frame 44 is formed by fixing the oil supply port member 440c to the recess 440a, so that water Wa such as rain water may stay in the recess 440a. is there. Then, when the amount of the water Wa staying increases, the water Wa flows and flows into the concave groove 440d via the drain port 440g. In the present embodiment, by forming the recessed groove 440d deeper than the recessed portion 440a, the water Wa in the recessed portion 440a can flow into the recessed groove 440d without resistance.
In addition, the efficiency of the waste_water | drain from the recessed part 440a can be improved by forming the drain port 440g so that the bottom part of the recessed part 440a may be contact | connected.

Since the concave groove 440d is formed so as to cross from the right surface Ri side of the upper frame 44 to the left surface Le side, the water Wa flowing into the concave groove 440d is the right surface Ri side or the left surface of the upper frame 44. It flows toward the side of Le.
Then, the water Wa that has flowed through the groove 440 d to the end of the upper frame 44 falls from the end of the upper frame 44.

When water Wa such as rainwater stays in the recess 440a of the oil supply unit 440 and the amount of water exceeds the capacity of the recess 440a, the water Wa overflows from the recess 440a. And the water Wa which overflowed from the recessed part 440a flows so that it may spread centering around the recessed part 440a.
Therefore, the water Wa overflowing from the concave portion 440a reaches the air outlet 44a (see FIG. 4) and flows into the air outlet 44a, and the housing 10 (see FIG. 4) through the hollow portion of the front frame 40 (see FIG. 4). May penetrate into the interior.

Therefore, in the present embodiment, as shown in FIG. 4, the air exhaust port 44 a and the oil supply portion 440 that open to the upper frame 44 are formed at positions that sandwich the concave groove 440 d.
With this configuration, the water Wa that overflows from the recess 440a (see FIG. 8) of the oil supply section 440 and flows toward the air outlet 44a flows into the groove 440d and does not reach the air outlet 44a. Therefore, the water Wa overflowing from the concave portion 440a does not enter the inside of the housing 10 through the air outlet 44a through the hollow portion of the front frame 40.

  Note that water Wa such as rainwater staying in the recess 440a (see FIG. 8) may flow inside the fuel filler member 440c (see FIG. 8). However, by forming a convex portion around the oil supply opening 440c1, the water Wa flowing into the oil supply port member 440c enters the inside of the housing 10 (see FIG. 4) from the oil supply opening 440c1. I can prevent it.

Further, as shown in FIG. 8, the recess 440a and the recess 440d of the oil filler 440 are communicated with each other, and the water Wa of the recess 440a is actively poured into the recess 440d.
With this configuration, water Wa such as rainwater flowing into the recess 440a flows into the recess 440d and the amount of water remaining in the recess 440a is reduced. And the quantity of the water Wa which overflows from the recessed part 440a can be reduced.

As described above, the water Wa overflowing from the recess 440a flows on the upper surface of the upper frame 44 so as to spread around the recess 440a. Then, it falls at a position where it reaches the end of the upper frame 44.
That is, the position where the water Wa falls from the upper frame 44 cannot be specified.

Therefore, the water Wa in the recess 440a is actively flowed into the groove 440d so that the water Wa falls from the position where the groove 440d in the upper frame 44 is formed.
With such a configuration, the position where the water Wa falls from the upper frame 44 can be specified.
Therefore, for example, the casing 10 is configured so that the connecting portion is not formed below the concave groove 440d, or only the connecting portion of the casing 10 below the concave groove 440d is caulked to form a watertight structure. The water Wa can be prevented from entering the inside of the housing 10 through the gap formed in the connecting portion of the housing 10 (see FIG. 4).

A water receiving member that receives the water Wa falling from the end of the upper frame 44 may be formed on the upper frame 44.
As shown by a two-dot chain line in FIG. 8, the front surface of the side wall forming the U-shape of the upper frame 44 is formed below the concave groove 440 d, for example, so that the upper part opens a substantially semicircular member having a cross-sectional shape. Attached along the longitudinal direction of the upper frame 44 from the end on the Fr side to the end on the back Rr side, a bowl-shaped water receiving member 44b is formed.
The water receiving member 44b is formed, for example, by fixing a member made of resin having a substantially semicircular cross section along the longitudinal direction of the upper frame 44 with a double-sided tape or the like.

In this way, by forming the bowl-shaped water receiving member 44b, the water Wa that has flowed through the concave groove 440d to the end of the upper frame 44 falls to the water receiving member 44b and is received.
Then, the water Wa dropped on the water receiving member 44b flows and drops to the end on the front Fr side or the end on the back Rr side of the upper frame 44 by the water receiving member 44b.

  Therefore, by attaching the water receiving member 44b as shown in FIG. 8, the end on the front Fr side where the water Wa does not enter the inside of the engine-driven work machine 1 (see FIG. 1) or the rear Rr side. The water Wa can be moved to the end, and the water Wa can be prevented from entering the housing 10 (see FIG. 4).

  8 illustrates the right surface Ri side, the water receiving member 44b may be similarly attached to the left surface Le side.

  For example, as shown in FIG. 8, you may provide the opening-and-closing lid 441 which opens and closes the oil supply part 440. As shown in FIG. The opening / closing lid 441 may be configured such that, for example, a plate-like member is attached to the upper frame 44 so as to rotate in the vertical direction by a hinge member (not shown), and the oil supply unit 440 is closed so as to cover the recess 440a.

In this manner, by opening the fuel filler opening 440c1 to the fuel filler member 440c, when fuel is injected into the fuel tank 1b (see FIG. 1), fuel leaking from the periphery of the fuel filler opening 440c1 is supplied to the fuel filler member 440c. It is possible to prevent the fuel from leaking around the engine-driven work machine 1.
Then, by forming the recess 440 a in the upper frame 44 and fixing the fuel filler member 440 c, the fuel filler member 440 c can be provided with the opening / closing lid 441 without protruding from the ceiling portion of the upper frame 44.

  And by providing the opening-and-closing lid 441, it can suppress that water Wa, such as rainwater, stays in the recessed part 440a, for example.

  Returning again to FIG. 4, the right frame 43 is provided on the right side Ri side of the engine-driven work machine 1. The right frame 43 is, for example, a plate-like member, and is provided in the engine-driven work machine 1 so as to be openable and closable, and constitutes an open / close door.

The right frame 43 is provided in the engine-driven work machine 1 so as to rotate, for example, about a rotation axis parallel to one side of the front side Fr and open and close.
The environment-friendly base 2 is provided with a locking portion 38 that locks the rotation of the right frame 43 on the upper surface portion 34a of the side surface portion 34 on the right surface Ri side.

As shown in FIG. 4, one side of the right frame 43 on the front Fr side is supported on the side wall forming the front frame 40 so as to be freely opened and closed via a hinge member 43a whose vertical axis serves as a rotation axis. .
The right frame 43 is formed of a shallow box-shaped member, and the width W2 of the plane portion 43d is substantially equal to the width of the opening formed between the front frame 40 and the rear frame 41, and the height H2 is the upper frame. 44 is substantially equal to the distance between the lower end of the side wall forming the U-shape and the upper surface portion 34 a of the side surface portion 34.

  That is, the right frame 43 is formed by being surrounded by a front frame 40 (see FIG. 4), a rear frame 41 (see FIG. 4), an upper frame 44 (see FIG. 4), and a side surface portion 34 (see FIG. 4). It is formed so as to fit into the opening, and opens and closes above the side surface 34 forming the frame.

  Further, the air inlet 43 b is opened in the flat portion 43 d of the right frame 43. A sound absorbing material 43c made of, for example, a sponge sheet or a urethane sheet is provided so as to be spread over substantially the entire box shape.

  FIG. 9 is a diagram illustrating the locking portion. As shown in FIG. 9, the locking portion 38 is a long member provided along the longitudinal direction of the upper surface portion 34 a of the side surface portion 34, and is provided on the upper surface portion 34 a of the side surface portion 34 on the right surface Ri side. 43 locks the rotation of the right frame 43 in the closed position where the casing is closed.

10 is a cross-sectional view taken along the line X4-X4 in FIG.
As shown in FIG. 10, the locking portion 38 has a substantially U-shaped cross section, and is fixed to the upper surface portion 34a of the side surface portion 34 so that the upper side is open.
A method for fixing the locking portion 38 to the upper surface portion 34 a is not limited, but a watertight structure can be formed between the side surface portion 34 and the locking portion 38 by fixing by, for example, continuous welding.

As described above, when the locking portion 38 having a substantially U-shaped cross section is fixed to the upper surface portion 34a of the side surface portion 34, the upper surface portion 34a is formed with an upstanding locking surface 38a. The rotation is locked by contacting the surface 38a.
In addition, if the sealing material 38b which consists of rubber | gum, for example is affixed on the locking surface 38a, the sealing performance between the right frame 43 and the locking part 38 can be improved.

  For example, when water Wa such as rainwater enters from the air inlet 43b (see FIG. 4) of the right frame 43, a part of the water Wa is brought into contact with the locking surface 38a of the locking portion 38 as shown in FIG. May exceed.

In the present embodiment, since the locking portion 38 is formed of a substantially U-shaped member, even if the water Wa exceeds the locking surface 38a, the water Wa stays in the U-shaped opening, and the side surface It does not flow into the leakage storage part 3a formed inside the part 34.
The cross-sectional shape of the locking portion 38 is not limited to a substantially U shape, and may be a substantially semicircular shape, a substantially J shape, or the like.

  Further, as shown in FIG. 9, the end portion on the front surface Fr side of the locking portion 38 according to the present embodiment extends to substantially the same position as the standing portion 37 a of the guide base 37, and the end on the back surface Rr side. The portion is configured to extend to above the inclined portion 401 d 2 of the drainage guide 401.

  In this way, the end of the locking portion 38 on the back surface Rr side extends to above the inclined portion 401d2 of the drainage guide 401, so that the water staying in the U-shaped opening of the locking portion 38 is retained. Even if Wa flows to the end portion on the rear surface Rr side, the water Wa is received by the inclined portion 401 d 2 of the drainage guide 401. Accordingly, the water Wa is discharged from the drain outlet 401f of the drainage guide 401 to the rear surface Rr side as drainage without flowing into the leaked substance reservoir 3a.

  Further, the end portion on the front side Fr side of the locking portion 38 extends to a position substantially equal to the standing portion 37 a of the guide base 37, so that it stays in the U-shaped opening of the locking portion 38. Even if the water Wa flows to the end portion on the front Fr side, the water Wa is received by the flat surface portion 37 b of the guide base 37. Accordingly, the water Wa is discharged as drainage from the drainage port 401f of the drainage guide 401 without flowing into the leakage storage part 3a.

As described above, the engine-driven work machine 1 (see FIG. 1) according to the present embodiment has the guide base 37 (see FIG. 4) and the drainage guide on the front Fr side of the environment-friendly base 2 (see FIG. 4). 401 (see FIG. 4).
The guide base 37 has a flat surface portion 37b (see FIG. 2A) that is a water receiving portion, and the water Wa received by the flat surface portion 37b flows into the inclined portion 401d2 (see FIG. 5) of the drainage guide 401. be able to.
Further, the drainage guide 401 has an inclined portion 401d2 and a flat portion 401d1 (see FIG. 5), which are water receiving portions, and a drain outlet 401f (see FIG. 5). The water Wa received by the inclined portion 401d2 and the guide The water Wa that has flowed into the inclined portion 401d2 from the flat portion 37b of the base 37 can flow to the flat portion 401d1.
And the water Wa which flowed into the flat part 401d1 can be discharged | emitted from the drain outlet 401f to the front Fr side as waste_water | drain.
With this configuration, for example, water Wa such as rainwater that enters the inside of the housing from the hollow portion of the front frame 40 (see FIG. 4) can be discharged as drainage without flowing into the leakage storage portion 3a (see FIG. 4). .
Therefore, there is an excellent effect that the leakage of the leakage can be prevented without increasing the amount of leakage stored in the leakage storage unit 3a.

Moreover, the drainage guide 401 (refer FIG. 4) was provided in the back surface Rr side of the environment-responsive base 2 (refer FIG. 4).
With this configuration, water Wa such as rainwater that enters the inside of the housing through a gap between the rear frame 41 (see FIG. 4) and another member such as the left frame 42 (see FIG. 4), for example, is stored in the leakage storage unit 3a. It can be discharged to the rear surface Rr side without flowing into (see FIG. 4).
Therefore, there is an excellent effect that the leakage of the leakage can be prevented without increasing the amount of leakage stored in the leakage storage unit 3a.

Further, a drain port 440g (see FIG. 8) is provided between a concave portion 440a (see FIG. 8) and a concave groove 440d (see FIG. 8) around the oil supply portion 440 formed in the upper frame 44 (see FIG. 4). Formed.
With this configuration, water Wa such as rainwater staying in the concave portion 440a can be discharged as drainage through the concave groove 440d.
Therefore, it is possible to suppress the water Wa such as rainwater staying in the concave portion 440a of the upper frame 44 from entering the inside of the housing, and the water Wa can be discharged without flowing into the leakage storage part 3a (see FIG. 4). Therefore, there is an excellent effect that the leakage of the leakage can be prevented without increasing the amount of leakage stored in the leakage storage unit 3a.

Further, the locking portion 38 (see FIG. 4) of the right frame 43 (see FIG. 4) forming the open / close door is formed of a member having a substantially U-shaped cross section, and the end on the front side Fr side is formed. The upper end of the back surface Rr was extended to above the drainage guide 401.
With this configuration, water Wa such as rainwater entering through the right frame 43 can be retained in the U-shaped opening. Furthermore, even if the water Wa flows through the locking portion 38, the water Wa can be discharged without flowing into the leakage storage portion 3a (see FIG. 4) via the drainage guide 401.
Therefore, there is an excellent effect that the leakage of the leakage can be prevented without increasing the amount of leakage stored in the leakage storage unit 3a.

  As described above, the engine-driven work machine according to the present embodiment prevents the water entering from the outside, such as rainwater, from entering the leak storage part, and increases the leakage stored in the leak storage part. It has an excellent effect of suppressing and preventing leakage of leakage.

DESCRIPTION OF SYMBOLS 1 Engine drive type work machine 1a Engine 1b Fuel tank 1c Work machine body 2 Environmentally friendly base (base)
3a Leakage storage part 10 Case 31 Bottom part (floor board)
32 Front (frame member)
33 Back (frame member)
34 Side (frame member)
37 Guide base (drainage member)
37b Plane part (water receiving part)
38 Locking part 40 Front frame 41 Rear frame 42 Left frame 43 Right frame (open / close door)
44 Upper frame (ceiling)
44a Ventilation port 401 Drainage guide (drainage member)
401d Bottom (water receiving part)
401d1 flat part (water receiving part)
401d2 inclined part (water receiving part)
401f Drain port 440 Refueling portion 440a Recessed portion 440b Refueling port 440d Recessed groove 440e Connecting member Fr Front surface Rr Back surface

Claims (3)

Engine,
A fuel tank for storing fuel to be supplied to the engine;
A working machine body driven by the engine,
An exhaust vent,
A concave groove for disposing a hook member;
A concave portion in which a fuel filler opening for injecting fuel into the fuel tank is open, and a rainwater intrusion prevention structure for an engine-driven working machine having a casing formed in a ceiling,
With an open / close lid that can be closed to cover the recess,
In the recess, a box-shaped oil supply port member having an oil supply opening opened at the bottom of an area larger than the opening area of the oil supply port is formed so that the oil supply port and the oil supply opening communicate with each other. And a convex portion is formed around the oil supply opening,
The concave groove is formed across from one end of the ceiling portion to the other end,
The structure for preventing rainwater intrusion, wherein the exhaust port and the concave portion are formed at positions sandwiching the concave groove.   The rainwater intrusion prevention structure according to claim 1, wherein the concave portion communicates with the concave groove.   The rainwater intrusion prevention structure according to claim 1, wherein the concave groove is formed deeper than the concave portion.

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