JP6638717B2 - Construction machine car body - Google Patents

Description

  The present invention relates to a car body of a construction machine.

  For example, Patent Document 1 (see FIG. 1) describes a car body of a conventional construction machine. A jack-up device for lifting the car body or the like with respect to the ground is attached to the car body described in the document. In the technique described in FIG. 1 of the document, the arm of the jack-up device is attached to the car body main body. An extendable cylinder is attached to this arm.

JP 2006-2900020 A

  When lifting the car body or the like, a vertical bending force acts on this arm. Therefore, it is important to secure the bending strength of the arm. Therefore, it is conceivable to increase the vertical width (height, thickness) of the arm in order to improve the bending strength of the arm. When the vertical width of the arm is increased, it is necessary to increase the vertical width of the mounting portion of the arm to the car body. Therefore, in order to increase the vertical width of the mounting portion of the arm, it is conceivable to increase (thicken) the vertical width of the car body body. However, increasing the vertical width of the car body body may increase the mass of the car body body.

  In order to increase the vertical width of the arm, it is conceivable to increase the position of the upper surface of the arm without changing the position of the lower surface of the arm. Then, the position of the joint between the arm and the cylinder may increase. Then, the upper end of the cylinder may interfere with the upper swing body. In addition, when the position of the connecting portion is increased, the distance from the ground to the connecting portion becomes longer when the jack-up device is used. Then, the bending moment of the cylinder may increase.

  Therefore, the present invention provides a construction that can increase the vertical width of the arm without increasing the vertical width of the car body main body, can suppress the increase in the mass of the car body main body, and can arrange the arm at a low position. The purpose is to provide the car body of the machine.

  The car body of the construction machine of the present invention has an arm for supporting the cylinder of the jack-up device. The car body includes a car body main body and a bracket. The bracket protrudes outward in the front-rear direction from the car body main body, and the arm is attached to the bracket. The car body main body includes a car body upper plate forming an upper surface of the car body main body, and a car body lower plate forming a bottom surface of the car body main body. The bracket includes an upper bracket and a lower bracket. The upper bracket is provided on the car body upper plate. The lower bracket is provided on the lower plate of the car body, and vertically opposes the upper bracket. The upper surface of the lower bracket is disposed below the upper surface of the car body lower plate. The lower surface of the lower bracket is disposed below the lower surface of the car body lower plate.

  With the above configuration, the arm width can be increased in the vertical direction without increasing the vertical width of the car body main body, an increase in the mass of the car body main body can be suppressed, and the arm can be arranged at a lower position.

It is the figure which looked at the construction machine 1 at the time of transportation from the side. FIG. 2 is a view of the car body 30 shown in FIG. 1 as viewed from below. FIG. 3 is an enlarged view of a bracket 60 and the like shown in FIG. 2. FIG. 4 is a sectional view taken along arrow F4-F4 in FIG. 3. FIG. 5 is a diagram corresponding to FIG. 4 of a second embodiment. FIG. 7 is a diagram corresponding to FIG. 3 of a third embodiment. FIG. 7 is a diagram corresponding to FIG. 4 of a third embodiment, and is a cross-sectional view taken along line F7-F7 in FIG. 6. FIG. 14 is a diagram corresponding to FIG. 3 of a fourth embodiment.

(1st Embodiment)
The car body 30 of the construction machine 1 according to the first embodiment will be described with reference to FIGS.

  As shown in FIG. 1, the construction machine 1 is a machine that performs work such as construction work, and is movable. For example, the construction machine 1 is a crane provided with a boom. This boom may be a telescopic boom or a lattice boom. The construction machine 1 includes an upper swing body 10 and a lower traveling body 20.

  The upper revolving superstructure 10 is disposed on the upper side Z1 with respect to the lower traveling superstructure 20. The upper revolving unit 10 is attached to the lower traveling unit 20 via a revolving bearing B, and is capable of revolving around the revolving center O (see FIG. 2) with respect to the lower traveling unit 20.

  As shown in FIG. 2, the lower traveling body 20 includes a crawler 21, a jack-up device 25, and a car body 30.

  The crawler 21 is a part that allows the construction machine 1 to travel. The crawlers 21 are provided on the left and right sides (both sides in the horizontal direction Y) of the car body 30. The details of the direction such as the “lateral direction Y” will be described later. Each of the left and right crawlers 21 extends in the front-rear direction X. The space (width) in the horizontal direction Y between the left and right crawlers 21 is variable. FIG. 2 shows a state in which the crawler 21 is arranged at the position of the outermost side Y1 in the lateral direction on one side (upper side in FIG. 2) with respect to the center line L. On the other side with respect to the center line L, a state is shown in which the crawler 21 is arranged at the position of the innermost side Y2 in the lateral direction. The width of the left and right crawlers 21 in the horizontal direction Y may not be variable.

  The jack-up device 25 (trans lifter) is a device that lifts the car body 30 with respect to the ground as shown in FIG. The jack-up device 25 is used to lift the car body 30 to a position higher than the bed C when loading and unloading the car body 30 with respect to the bed C of a transportation vehicle (such as a trailer). The jack-up device 25 is used to lift the crawler 21 with respect to the ground when the crawler 21 (see FIG. 2) is attached to and detached from the car body 30. A plurality of jack-up devices 25 are provided, for example, four (see FIG. 2). The jack-up device 25 has a use state 25A1 and a storage state 25A2. The jack-up device 25 includes an arm 25a, a coupling portion 25b, and a cylinder 25c. In FIGS. 1 and 2, the reference numerals of the arm 25 a, the coupling portion 25 b, and the cylinder 25 c are given only to a part of the plurality of jack-up devices 25.

  The arm 25a (trans lifter arm) is a structure that connects the car body 30 and the cylinder 25c. As shown in FIG. 2, the arm 25a is rotatable with respect to the car body 30 about a rotation axis in the vertical direction Z. The cylinder 25c is extendable and contractable, and is, for example, a hydraulic cylinder or the like. The cylinder 25c is attached to the arm 25a via the coupling portion 25b, and is supported by the arm 25a. The cylinder 25c is rotatable with respect to the arm 25a about a horizontal rotation axis (see FIG. 1).

  The car body 30 is a structure provided at the center of the lower traveling body 20. The crawler 21 and the jack-up device 25 are attached to the car body 30. The car body 30 includes a car body main body 40, a swivel seat 50, and a bracket 60.

(direction)
As shown in FIG. 1, the direction in which the rotation axis of the upper swing body 10 extends with respect to the lower traveling body 20 (vertical direction) is defined as a vertical direction Z. The side from the lower traveling structure 20 toward the upper revolving structure 10 is defined as an upper side Z1, and the opposite side is defined as a lower side Z2. As shown in FIG. 2, the direction in which the crawler 21 extends is referred to as a front-rear direction X. In the front-rear direction X, the side away from the turning center O is referred to as a front-rear outside X1, and the side approaching the turning center O is referred to as a front-rear inner X2. A direction orthogonal to the front-rear direction X and the vertical direction Z is defined as a horizontal direction Y. In the lateral direction Y, the side away from the turning center O is referred to as a lateral outside Y1, and the side approaching the turning center O is referred to as a lateral inside Y2.

  The car body main body 40 includes a car body main body central portion 41 and an axle 43. 4, the car body main body 40 includes a car body upper plate 47 and a car body lower plate 48.

  As shown in FIG. 2, the car body main body central portion 41 is a portion that constitutes a central portion in the front-rear direction X of the car body main body 40. The car body main body center portion 41 supports the turning seat 50 from the lower side Z2 (see FIG. 1). The axle 43 is a portion to which the crawler 21 is attached. The axles 43 are provided before and after the car body main body central portion 41 (on both sides of the outer side X1 in the front-rear direction). Each of the front and rear axles 43 extends in the lateral direction Y.

  As shown in FIG. 4, the car body upper plate 47 is a plate-like member that forms the upper surface (the upper Z1 surface) of the car body main body 40. The car body upper plate 47 forms the upper surface of the axle 43. The car body upper plate 47 may constitute the upper surface of the car body main body central portion 41 shown in FIG. Note that the upper surface of the axle 43 and the upper surface of the car body main body central portion 41 may be integrally formed (in a single plate) or may be separate bodies.

  As shown in FIG. 4, the car body lower plate 48 is a plate-like member that forms a bottom surface (a surface of the lower side Z2) of the car body main body 40. The car body lower plate 48 forms a bottom surface of the axle 43. The car body lower plate 48 may constitute the bottom surface of the car body main body central portion 41 shown in FIG. In addition, the bottom surface of the axle 43 and the bottom surface of the car body main body central portion 41 may be integrally formed (in a single plate) or may be separate bodies. As shown in FIG. 4, the upper surface of the car body lower plate 48 is referred to as a car body lower plate upper surface 48t. The lower surface of the car body lower plate 48 is referred to as a car body lower plate lower surface 48u.

  The swivel seat 50 is a portion to which the swivel bearing B is attached, as shown in FIG. The swivel seat 50 projects from the car body main body 40 to the upper side Z1. Note that the swivel seat 50 is not included in the car body main body 40. The car body upper plate 47 (see FIG. 4) constituting the upper surface of the car body main body 40 is not the upper surface of the swivel seat 50.

  The bracket 60 is a part to which the arm 25a is attached (arm attachment part). The bracket 60 projects outwardly in the front-rear direction X1 beyond the car body main body 40 (than the axle 43). As shown in FIG. 2, the brackets 60 are provided at a total of four places on the front and rear sides (on both sides in the front-rear direction X) and on the left and right sides (on both sides in the horizontal direction Y) of the car body body 40. Hereinafter, one bracket 60 will be described. As shown in FIG. 4, the bracket 60 includes an upper bracket 70 and a lower bracket 80.

  The upper bracket 70 is provided on the upper plate 47 of the car body. The upper bracket 70 protrudes outwardly in the front-rear direction X1 beyond the car body upper plate 47, and protrudes outwardly in the front-rear direction X1 than the axle 43. The upper bracket 70 may be formed integrally with the car body upper plate 47 (in a single plate) or may be separate from the car body upper plate 47.

  The lower bracket 80 is provided on the car body lower plate 48. At least a portion of the lower bracket 80 projects outwardly in the front-rear direction X1 beyond the car body lower plate 48, and projects outwardly in the front-rear direction X1 beyond the axle 43. The lower bracket 80 faces the upper bracket 70 in the vertical direction Z. The arm 25a is arranged between the lower bracket 80 and the upper bracket 70. The lower bracket 80 is a member separate from the car body lower plate 48 (not a single plate). The lower bracket 80 is fixed to the car body lower plate lower surface 48u. The lower bracket 80 is also fixed to a front surface X1 of the car body lower plate 48 in the front-rear direction (details of fixing will be described later). The lower bracket 80 includes a main body member 81 and a plate joining member 83.

  The main body member 81 is a part (main body part) that constitutes most of the lower bracket 80. The main body member 81 is a plate-shaped member. The main body 81 includes an overlapping portion 81a and a main body outer portion 81b. The overlapping portion 81a and the body material outer portion 81b are integrally formed so as to be continuous in the front-rear direction X (a single plate). In FIG. 4, the boundary between the overlapping portion 81a and the main body material outer portion 81b is indicated by a two-dot chain line. In the example shown in FIG. 3, one main body member 81 is provided across the lower brackets 80 on the left and right (two places in the horizontal direction Y). The main body member 81 does not have to be provided over a plurality of lower brackets 80 (the same applies to the plate joining member 83).

  As shown in FIG. 4, the overlapping portion 81 a is a portion that improves the strength of the lower bracket 80 by being overlapped (doubled) with the car body lower plate 48. The overlapping portion 81a is a portion of the main body 81 that is closer to the inside in the front-back direction X2 than the end of the car body lower plate 48 to the outside in the front-rear direction X1. The overlapping portion 81a extends parallel to the car body lower plate lower surface 48u, is arranged so as to overlap the car body lower plate lower surface 48u, and is fixed to the car body lower plate lower surface 48u. In the example shown in FIG. 4, one overlapping portion 81a is provided (the car body upper plate 47 and the overlapping portion 81a are doubled), but two or more overlapping portions may be provided (the car body upper plate). 47 and the overlapping portion 81a may be three or more).

  The main body material outer portion 81b is a portion of the main body material 81 that is located on the outer side in the front-rear direction X1 of the end of the car body lower plate 48 in the front-rear direction X1. The main body material outer portion 81b is disposed on the lower side Z2 than the car body lower plate lower surface 48u.

  The plate joining member 83 has a function of suppressing stress concentration due to bending of the upper bracket 70 and the like. The details of the function of suppressing stress concentration are as follows. If the plate joining member 83 is not provided, the cross section (not shown) of the car body lower plate 48 and the lower bracket 80 as viewed in the front-rear direction X changes abruptly at the X1 end of the car body lower plate 48 in the front-rear direction. I do. The area of this cross-section decreases rapidly toward the outer side X1 in the front-rear direction at the end of the outer side X1 in the front-rear direction of the car body lower plate 48. Therefore, the plate joining material 83 is provided so as to suppress concentration of bending stress due to a sudden change in cross section. Specifically, the plate joining material 83 extends from the surface of the car body lower plate 48 in the front-rear outside X1 to the front-rear outside X1. The plate joining material 83 is fixed to a surface of the car body lower plate 48 on the outer side X1 in the front-rear direction. This fixing is preferably fixing by welding (fixing at the welding portion 83y) (details of welding will be described later). The plate joining member 83 is stacked on the main body material outer portion 81b in the up-down direction Z, disposed above the main material material outer portion 81b, and fixed to the main material material outer portion 81b. This fixing is preferably fixing by welding (fixing at the welded portion 81y) (described later).

  The plate joining member 83 is disposed between the body member outer portion 81b and the arm 25a in the vertical direction Z. By adjusting the thickness of the plate joining material 83 in the vertical direction Z, it is possible to suppress the backlash of the arm 25a with respect to the bracket 60 in the vertical direction Z.

(Position of lower bracket lower surface 80u)
The lower surface of the lower bracket 80 is referred to as a lower bracket lower surface 80u. The lower bracket lower surface 80u is arranged so as to ensure the strength of the lower bracket 80 as much as possible. Specifically, lower bracket lower surface 80u is arranged on lower side Z2 than car body lower plate lower surface 48u. More specifically, the lower surface of the portion of the lower bracket 80 that faces the arm 25a in the up-down direction Z is disposed below the car body lower plate lower surface 48u below Z2. In the example shown in FIG. 4, the lower surface of the body material outer portion 81b is disposed on the lower side Z2 than the car body lower plate lower surface 48u.

(Position of the upper surface of the lower bracket 80t)
The upper surface of the lower bracket 80 is referred to as a lower bracket upper surface 80t. The lower bracket upper surface 80t is arranged so that the width (height) of the mounting portion of the arm 25a to the bracket 60 in the vertical direction Z can be as large as possible. Specifically, the lower bracket upper surface 80t is disposed on a lower side Z2 than the car body lower plate upper surface 48t. More specifically, the upper surface of a portion of the lower bracket 80 that faces the arm 25a in the up-down direction Z is disposed below the upper surface 48t of the car body lower plate. In the example shown in FIG. 4, the upper surface of the plate joining material 83 is arranged on the lower side Z2 than the upper surface 48t of the car body lower plate.

(Thickness T80 of lower bracket 80)
The thickness in the vertical direction Z of a portion of the lower bracket 80 facing the arm 25a in the vertical direction Z is referred to as a thickness T80. In the example shown in FIG. 4, the thickness T80 is the thickness (total thickness) of the main body material outer portion 81b and the plate joining material 83. It is preferable that the thickness T80 be set so that the car body lower plate 48 can be reduced in weight and the strength of the lower bracket 80 can be ensured. Specifically, the thickness T80 is greater than the thickness T48 of the car body lower plate 48 in the vertical direction Z.

  Here, when the jack-up device 25 is used (see the use state 25A1 in FIG. 1), the own weight of the car body 30 and the like acts on the upper bracket 70 (the upper bracket 70 supports the own weight). On the other hand, the weight does not act on the lower bracket 80 when the jack-up device 25 is used. Therefore, the strength of the lower bracket 80 may be lower than that of the upper bracket 70. Therefore, the thickness T80 is preferably set so that the lower bracket 80 can be reduced in weight and the strength of the upper bracket 70 can be ensured. Specifically, the thickness T80 is smaller than the thickness T70 in the vertical direction Z of a portion of the upper bracket 70 facing the arm 25a in the vertical direction Z.

(Welded part 81y of main body material 81)
The welding of the main body member 81 to the plate joining member 83 and the car body lower plate 48 is preferably performed so as to suppress cracks in the welded portion 81y. Specifically, it is preferable to provide the welding portion 81y as follows. As shown in FIG. 3, when viewed from the lower side Z <b> 2, the plate joining material 83 and the car body lower plate 48 extend outside (below) the outer circumference of the main body material 81 over the entire circumference (one circumference) of the main body material 81. Outside of the main body member 81 as viewed from the side Z2). Then, the lower surfaces of the plate joining member 83 and the car body lower plate 48 and the entire outer periphery of the main body member 81 are fixed by welding (welded portion 81y shown in FIG. 4).

(Welded portion 83y of plate joint 83)
Further, as described above, the cross section (not shown) of the car body lower plate 48 and the lower bracket 80 shown in FIG. 4 as viewed from the front-rear direction X is an end of the car body lower plate 48 in the front-rear outer side X1. Changes rapidly. It is preferable that the plate joining member 83 and the car body lower plate 48 be fixed so as to suppress the stress at the cross section changing portion and suppress the crack in the welded portion 83y. Specifically, it is preferable that the plate joining material 83 and the car body lower plate 48 are fixed by welding (welded portion 83y). In general, butt welding has higher weld strength than fillet welding. Therefore, for example, compared with a case where the plate joining material 83 is not provided and the end portion X1 of the car body lower plate 48 in the front-rear direction and the body material outer portion 81b are fixed by fillet welding, the plate joining material is not provided. When the 83 and the car body lower plate 48 are fixed by butt welding, the strength of the welded portion 83y can be improved. As a result, the strength of the lower bracket 80 can be improved.

(transport)
The construction machine 1 shown in FIG. 1 is transported, for example, as follows. The car body 30 is lifted with respect to the ground by the jack-up device 25 (use state 25A1). In this state, the crawler 21 (see FIG. 2) is removed from the car body 30. In addition, the loading platform C is disposed below the car body 30 on the lower side Z2. Then, the car body 30 is mounted on the carrier C by the contraction of the cylinder 25c. At this time, a support member D that supports the car body main body 40 may be provided between the car body lower plate 48 (see FIG. 4) and the carrier C. In this case, the car body main body 40 is supported (deposited) on the carrier C from the lower side Z2 via the support member D. On the other hand, a gap in the vertical direction Z is provided between the lower bracket 80 and the loading platform C (the lower bracket 80 is not deposited on the loading platform C). Next, the jack-up device 25 is set to the stored state 25A2. In this state, the construction machine 1 is transported. At this time, the height from the ground to the highest part of the upper-part turning body 10 is the transport height. When transporting on public roads, this transportation height is restricted by law. As described below, when the car body 30 is transported using the support member D, the transport height can be suppressed. Note that the car body 30 may be transported in a state where the lower bracket 80 is left on the carrier C without using the support member D.

(effect)
The effects of the car body 30 of the construction machine 1 shown in FIG. 1 are as follows.

(Effect of the first invention)
The car body 30 of the construction machine 1 has an arm 25a for supporting the cylinder 25c of the jack-up device 25 attached thereto. The car body 30 includes a car body main body 40 and a bracket 60. The bracket 60 projects outwardly in the front-rear direction X1 beyond the car body main body 40. The arm 25a is attached to the bracket 60. As shown in FIG. 4, the car body main body 40 includes a car body upper plate 47 forming the upper surface of the car body main body 40 and a car body lower plate 48 forming the bottom surface of the car body main body 40. The bracket 60 includes an upper bracket 70 and a lower bracket 80. The upper bracket 70 is provided on the upper plate 47 of the car body. The lower bracket 80 is provided on the car body lower plate 48 and faces the upper bracket 70 in the vertical direction Z.

  [Configuration 1-1] The upper surface of the lower bracket 80 (the lower bracket upper surface 80t) is disposed on the lower side Z2 than the upper surface of the car body lower plate 48 (the car body lower plate upper surface 48t).

  [Configuration 1-2] The lower surface of the lower bracket 80 (lower bracket lower surface 80u) is disposed on a lower side Z2 than the lower surface of the car body lower plate 48 (car body lower plate lower surface 48u).

  The car body 30 includes the above [Configuration 1-1]. Therefore, an arm having a width in the vertical direction Z that is larger than the distance between the car body upper plate 47 and the car body lower plate 48 without increasing the distance in the vertical direction Z between the car body upper plate 47 and the car body lower plate 48. 25a can be attached to the bracket 60. Therefore, the width of the arm 25a in the vertical direction Z can be increased without increasing the width of the car body body 40 in the vertical direction Z.

  According to the above [Configuration 1-1], it is not necessary to increase the distance between the car body upper plate 47 and the car body lower plate 48 in the up-down direction Z, so that the following effects can be obtained. A member (such as a vertical plate) connecting the car body upper plate 47 and the car body lower plate 48 in the vertical direction Z is lighter than a case where the distance between the car body upper plate 47 and the car body lower plate 48 in the vertical direction Z is increased. Can be Therefore, the mass of the car body main body 40 can be suppressed.

  In addition, since the width of the arm 25a in the vertical direction Z can be increased by the above [Configuration 1-1], the following [Effect 1a] and [Effect 1b] can be obtained. [Effect 1a] By increasing the width of the arm 25a in the vertical direction Z, the cross-sectional performance of the arm 25a can be improved, and the strength of the arm 25a against bending in the vertical direction Z can be improved. [Effect 1b] As a result that the width of the arm 25a in the vertical direction Z can be increased, the coupling portion 25b between the arm 25a and the cylinder 25c shown in FIG. 1 can be increased. Therefore, the connection between the arm 25a and the cylinder 25c can be strengthened. Therefore, the strength of the jack-up device 25 can be improved.

  Further, according to the above [Configuration 1-1], as shown in FIG. 4, the lower surface of the arm 25a can be disposed on the lower side Z2 than the upper surface 48t of the car body lower plate. Therefore, the position of the lower surface of the arm 25a in the vertical direction Z is the same as the position of the upper surface 48t of the car body lower plate 48t in the vertical direction Z or the upper position Z1. ). Therefore, the connecting portion 25b between the arm 25a and the cylinder 25c shown in FIG. 1 can be disposed on the lower side Z2. Therefore, the following [Effect 1c] and [Effect 1d] are obtained. [Effect 1c] Since the coupling portion 25b can be disposed on the lower side Z2, the coupling portion 25b can be disposed at a position closer to the ground when the jack-up device 25 is used (use state 25A1). Therefore, in the cylinder 25c, the distance from the ground to the coupling portion 25b can be reduced. Therefore, the bending moment of the cylinder 25c when the jack-up device 25 is used can be suppressed, so that the strength of the cylinder 25c against bending in the horizontal direction can be improved. Therefore, the strength of the jack-up device 25 can be improved. [Effect 1d] Since the coupling portion 25b can be disposed on the lower side Z2, the upper Z1 end of the cylinder 25c can be disposed on the lower side Z2. Therefore, interference of the cylinder 25c with the upper swing body 10 can be suppressed.

  The car body 30 illustrated in FIG. 4 includes the above [Configuration 1-2]. Therefore, the position of the lower bracket lower surface 80u in the vertical direction Z is the same as the position of the lower surface 48u of the car body lower plate 48u in the vertical direction Z or the upper position Z1. Thickness can be secured. Therefore, the strength of the lower bracket 80 against bending in the vertical direction Z can be secured. Moreover, since the strength of the lower bracket 80 can be ensured by the above [Configuration 1-2], the following effects can be obtained. Here, a case where the car body lower plate lower surface 48u and the lower bracket lower surface 80u have the same height will be considered. In this case, if the lower bracket 80 is made thicker by increasing the thickness of the car body lower plate 48 in order to secure the strength of the lower bracket 80, the mass of the car body lower plate 48 will increase. On the other hand, in the car body 30, since the strength of the lower bracket 80 can be ensured by the above [Configuration 1-2], it is not necessary to secure the strength of the lower bracket 80 by making the car body lower plate 48 thick. Therefore, an increase in the mass of the car body lower plate 48 can be suppressed. Therefore, an increase in the mass of the car body main body 40 can be suppressed.

  The following effects may be obtained by the above [Configuration 1-1]. When the car body 30 is transported, the car body main body 40 is supported by the carrier C from the lower side Z2 via the support member D, and a gap in the vertical direction Z is provided between the lower bracket 80 and the carrier C. (Hereinafter, “at the time of transporting the car body 30 using the support member D”). When transporting the car body 30 using the support member D, the following effects can be obtained. In order to increase the width of the arm 25a in the vertical direction Z, the distance between the car body upper plate 47 and the car body lower plate 48 in the vertical direction Z is increased. Then, when transporting the car body 30 using the support member D, the height from the ground to the car body upper plate 47 increases. On the other hand, in the above [Configuration 1-1], the width of the arm 25a in the vertical direction Z can be increased without increasing the distance in the vertical direction Z between the car body upper plate 47 and the car body lower plate 48. Therefore, compared with the case where it is necessary to widen the distance in the vertical direction Z between the car body upper plate 47 and the car body lower plate 48, the car body upper plate 47 is moved from the ground when the car body 30 is transported using the support member D. Height can be lowered. Therefore, the height (for example, the upper revolving unit 10 (see FIG. 1)) of the object disposed above the car body upper plate 47 (see FIG. 1) can be reduced. Therefore, the transportation height at the time of transportation of the car body 30 using the support member D can be suppressed. As a result, the car body 30 can be easily transported.

(Effect of the Second Invention)
[Configuration 2] A thickness T80 in the vertical direction Z of a portion of the lower bracket 80 facing the arm 25a in the vertical direction Z is greater than a thickness T48 in the vertical direction Z of the car body lower plate 48.

  According to the above [Configuration 2], the bending strength in the vertical direction Z of the lower bracket 80 can be improved as compared with the case where the thickness T80 of the lower bracket 80 is equal to or less than the thickness T48 of the car body lower plate 48. In the above [Configuration 2], the thickness T48 of the car body lower plate 48 is smaller than the thickness T80 of the lower bracket 80. Therefore, the weight of the car body lower plate 48 can be reduced.

  The following effects may be obtained by the above [Configuration 2]. In the above [Configuration 2], the thickness T48 of the car body lower plate 48 is smaller than the thickness T80 of the lower bracket 80. Therefore, the height from the ground to the car body upper plate 47 can be reduced when the car body 30 is transported using the support member D. Therefore, the height (for example, the upper revolving unit 10 (see FIG. 1)) of the object disposed above the car body upper plate 47 (see FIG. 1) can be reduced. Therefore, the transportation height at the time of transportation of the car body 30 using the support member D can be reduced. As a result, the car body 30 can be easily transported.

(Effect of the third invention)
[Configuration 3] The thickness T80 in the vertical direction Z of the portion of the lower bracket 80 facing the arm 25a in the vertical direction Z is the vertical direction of the portion of the upper bracket 70 facing the arm 25a in the vertical direction Z. It is thinner than the thickness T70 of Z.

  According to the above [Configuration 3], the weight of the lower bracket 80 can be reduced as compared with the case where the thickness T80 of the lower bracket 80 is equal to or greater than the thickness T70 of the upper bracket 70.

  Here, when the jack-up device 25 is used (see the use state 25A1 in FIG. 1), the own weight of the car body 30 and the like acts on the upper bracket 70, and a bending force in the vertical direction Z acts on the upper bracket 70. . Therefore, in the above [Configuration 3], the thickness T70 of the upper bracket 70 is larger than the thickness T80 of the lower bracket 80. Therefore, the bending strength of the upper bracket 70 in the vertical direction Z can be improved as compared with the case where the thickness T70 of the upper bracket 70 is equal to or less than the thickness T80 of the lower bracket 80.

(Effect of the fourth invention)
[Configuration 4] The lower bracket 80 is a member separate from the car body lower plate 48, and is fixed to the car body lower plate lower surface 48u.

  According to the above [Configuration 4], the lower bracket 80 and the car body lower plate 48 can be separately and easily manufactured as compared with the case where the lower bracket 80 and the car body lower plate 48 are integrally manufactured. In addition, comparing the car body main body 40 without the lower bracket 80 attached thereto and the car body main body 40 provided integrally with the lower bracket 80, the former is lighter. Therefore, the weight of the car body main body 40 in a state where the lower bracket 80 is not attached (for example, the car body main body 40 during the manufacture of the car body 30) can be reduced.

(Effect of the fifth invention)
[Configuration 5] The lower bracket 80 includes an overlapping portion 81a. The overlapping portion 81a extends parallel to the car body lower plate lower surface 48u, is arranged so as to overlap the car body lower plate lower surface 48u, and is fixed to the car body lower plate lower surface 48u.

  With the above [Configuration 5], the lower bracket 80 can be firmly fixed to the car body lower plate 48 as compared with the case where the overlapping portion 81a is not provided. Therefore, the bending strength of the lower bracket 80 in the vertical direction Z can be improved.

(Effect of the sixth invention)
A portion of the lower bracket 80, which is outside the car body lower plate 48 in the front-rear direction X1 with respect to the car body lower plate 48, includes a main body material outer portion 81b and a plate joining material 83. The main body material outer portion 81b is disposed on the lower side Z2 than the car body lower plate lower surface 48u.

  [Configuration 6-1] The plate joining member 83 is disposed between the outer side portion 81b of the main body member and the arm 25a in the vertical direction Z.

  [Configuration 6-2] The plate joining material 83 extends from the surface of the car body lower plate 48 in the front-rear direction outside X1 to the front-rear direction outside X1.

  By adjusting the thickness of the plate joining material 83 in the vertical direction Z according to the above [Configuration 6-1], it is possible to suppress the play of the arm 25a with respect to the bracket 60 in the vertical direction Z.

  According to the above [Configuration 6-2], the following effects can be obtained. In the above [Configuration 1-1], the lower bracket upper surface 80t is arranged on the lower side Z2 than the car body lower plate upper surface 48t. Therefore, the cross section of the car body lower plate 48 and the lower bracket 80 as viewed in the front-rear direction X may suddenly change at the end of the car body lower plate 48 on the front-rear outside X1. Therefore, when the lower bracket 80 receives a bending force in the vertical direction Z, stress concentration may occur at this cross-section change portion. Therefore, the car body 30 includes the above [Configuration 6-2]. Therefore, compared to the case where the plate joining material 83 does not exist at the end of the car body lower plate 48 in the front-rear direction X1, the cross-sectional change at the end of the car body lower plate 48 at the front-rear outside X1 can be reduced. Therefore, it is possible to suppress the concentration of stress at the section where the cross section changes. Therefore, the bending strength of the lower bracket 80 in the vertical direction Z can be improved.

(Effect of the seventh invention)
[Configuration 7] An end portion X1 of the car body lower plate 48 on the outer side in the front-rear direction and the plate joining member 83 are fixed by welding (welded portion 83y).

  According to the above [Configuration 7], the end X1 of the car body lower plate 48 in the front-rear direction and the plate joining member 83 are fixed by mechanical fixing (bolts or the like) or fixing with an adhesive. The strength of the fixing portion (welded portion 83y) can be improved.

(Effect of the eighth invention)
[Configuration 8] The main body outer portion 81b is formed integrally with the overlapping portion 81a in the front-rear direction X. The body material outer portion 81b and the overlapping portion 81a constitute the body material 81. As shown in FIG. 3, when viewed from the lower side Z <b> 2, the plate joining member 83 and the car body lower plate 48 are located outside the outer periphery of the main body member 81 (from the lower side Z <b> 2 (Outside of the main body 81 seen). The upper surfaces of the plate joining member 83 and the car body lower plate 48 and the entire outer periphery of the main body member 81 are fixed by welding (welded portion 81y).

  According to the above [Configuration 8], the stress generated in the welded portion 81y can be suppressed as compared with a case where the welded portion 81y (see FIG. 4) is not continuous over the entire outer periphery of the main body member 81 (a case where the welded portion 81y is interrupted halfway). , Cracks are less likely to occur in the welded portion 81y. As a result, the strength of the lower bracket 80 can be improved.

(2nd Embodiment)
With reference to FIG. 5, the difference between the car body 230 of the second embodiment and the first embodiment will be described. Note that, of the car body 230 of the second embodiment, common points to the first embodiment are denoted by the same reference numerals as in the first embodiment, and description thereof is omitted. In addition, about the point which abbreviate | omits description of a common point, description of other embodiment mentioned later is also the same. The car body 230 of the second embodiment includes a lower bracket 280 having a structure different from that of the lower bracket 80 of the first embodiment (see FIG. 4).

  The lower bracket 280 includes a main body 281 and a connecting portion 285. The lower bracket 280 does not include the plate joining material 83 (see FIG. 4). The differences of the main body 281 from the main body 81 (see FIG. 4) of the first embodiment are as follows. The upper surface of the main body member 281 is disposed on the lower side Z2 than the car body lower plate lower surface 48u. The main body 281 does not include the overlapping portion 81a (see FIG. 4). The connecting portion 285 connects the lower surface 48u of the car body lower plate and the main body 281 (for example, the X2 end of the main body 281 in the front-rear direction).

  In the lower bracket 280, the upper surface of the main body member 281 is disposed on the lower side Z2 than the lower surface 48u of the car body lower plate. Therefore, the width of the arm 25a in the vertical direction Z shown in FIG. 5 can be made larger than in the case where the upper surface of the main body member 81 contacts the lower surface 48u of the car body lower plate as shown in FIG. ) Can be placed on the lower side Z2.

(Third embodiment)
With reference to FIGS. 6 and 7, differences between the car body 330 of the third embodiment and the first embodiment will be described. The car body 330 shown in FIG. 7 includes a car body upper plate 347 and an upper bracket 370 which are different in structure from the first embodiment (see FIG. 4). FIG. 3 is a view of the bracket 60 and the like viewed from the lower side Z2, while FIG. 6 is a view of the bracket 60 and the like viewed from the upper side Z1.

  The car body upper plate 347 includes a car body upper plate recess 347a and a car body upper plate protrusion 347b. The upper surface of the car body upper plate 347 is referred to as a car body upper plate upper surface 347t. The lower surface of the car body upper plate 347 is referred to as a car body upper plate lower surface 347u.

  The car body upper plate recess 347a is configured such that the car body upper plate 347 does not interfere with the arm 25a. The car body upper plate recessed portion 347a is provided at the outer X1 end of the car body upper plate 347 in the front-rear direction. The car body upper plate recess 347a is formed so as to avoid a range where the arm 25a passes when the arm 25a rotates with respect to the bracket 60. Note that the range of the rotatable angle of the arm 25a with respect to the bracket 60 is limited to a predetermined range (not 360 ° rotatable). Therefore, the car body upper plate concave portion 347a may be formed so as to avoid a range where the arm 25a passes when the arm 25a rotates within a predetermined range with respect to the bracket 60.

  The car body upper plate projecting portion 347b is a portion for suppressing the concentration of stress in the vicinity of the end X1 in the front-rear direction of the car body upper plate 347 and suppressing the bending stress of the upper bracket 370 in the vertical direction Z. The car body upper plate protrusion 347b is adjacent to the car body upper plate recess 347a in the lateral direction Y and is disposed on the left and right of the car body upper plate recess 347a. The car body upper plate projection 347b projects outwardly in the front-rear direction X1 beyond the car body upper plate recess 347a.

  By providing the car body upper plate projection 347b, the front and rear direction of the car body upper plate 347 is provided as compared with the case where the car body upper plate 347 is provided only on the inside X2 in the front and rear direction with respect to the “range through which the arm 25a passes”. The end portion of the outer side X1 can be disposed more outwardly in the front-rear direction X1. Therefore, it is possible to increase the cross-sectional area of the car body upper plate 347 and a main body member 371 (described later) near the end of the car body upper plate 347 in the front-rear outside X1 as viewed in the front-rear direction X direction. In addition, it can be said that the overlapping portion 371a overlapping the car body upper plate 347 shown in FIG. 7 can be further extended to the outer side X1 in the front-rear direction. Therefore, the bending strength of the upper bracket 370 in the vertical direction Z can be further improved.

  The upper bracket 370 has a structure in which the lower bracket 80 is inverted in the vertical direction Z. The operational effects of the upper bracket 370 and the car body upper plate 347 are substantially the same as the operational effects of the lower bracket 80 and the car body lower plate 48. The upper bracket 370 includes a main body 371 (corresponding to the main body 81 of the lower bracket 80) and a plate joining material 373 (corresponding to the plate joining material 83). The main body member 371 includes an overlapping portion 371a (corresponding to the overlapping portion 81a) and a main body outer portion 371b (corresponding to the main body outer portion 81b).

  The lower surface of the upper bracket 370 is referred to as an upper bracket lower surface 370u (corresponding to the lower bracket upper surface 80t). The upper bracket lower surface 370u is arranged above the car body upper plate lower surface 347u (corresponding to the car body lower plate upper surface 48t) above Z1. Therefore, the width of the arm 25a in the vertical direction Z can be further increased without increasing the width in the vertical direction Z of the car body upper plate 347 and the car body lower plate 48.

  The upper surface of the upper bracket 370 is referred to as an upper bracket upper surface 370t (corresponding to the lower bracket lower surface 80u). The upper bracket upper surface 370t is disposed above the car body upper plate upper surface 347t (corresponding to the car body lower plate lower surface 48u) above Z1. Therefore, the thickness of the upper bracket 370 in the vertical direction Z can be secured, and the strength of the upper bracket 370 against bending in the vertical direction Z can be secured.

  The thickness T370 in the vertical direction Z (corresponding to the thickness T80 of the lower bracket 80) of a portion of the upper bracket 370 opposed to the arm 25a in the vertical direction Z is the thickness of the car body upper plate 347 in the vertical direction Z. It is thicker than T347 (corresponding to the thickness T48 of the car body lower plate 48). Therefore, the bending strength in the vertical direction Z of the upper bracket 370 can be improved.

  The upper bracket 370 is a member separate from the car body upper plate 347, and is fixed to the car body upper plate upper surface 347t. Therefore, upper bracket 370 and car body upper plate 347 can be easily manufactured separately.

  The overlapping portion 371a (corresponding to the overlapping portion 81a) extends parallel to the car body upper plate upper surface 347t (corresponding to the car body lower plate lower surface 48u) and is arranged so as to overlap the car body upper plate upper surface 347t. It is fixed to the upper surface 347t. Therefore, upper bracket 370 can be firmly fixed to car body upper plate 347.

  The plate joining material 373 (corresponding to the plate joining material 83) is disposed between the main body outer portion 371b (corresponding to the main body outer portion 81b) and the arm 25a in the vertical direction Z. Thus, unlike the plate joining member 83 of the lower bracket 80, the following effects can be obtained. By adjusting the thickness in the vertical direction Z of the plate joining material 373, the position of the main body outer portion 371b with respect to the arm 25a in the vertical direction Z can be adjusted. The thicker the plate joining material 373, the more the main body outer portion 371b can be disposed on the upper side Z1 with respect to the arm 25a. Since the body material outer portion 371b is fixed to the car body body 40, the height of the car body body 40 with respect to the arm 25a can be adjusted by adjusting the thickness of the plate joining material 373 in the vertical direction Z.

  The plate joining material 373 extends from the front-rear outer surface X1 of the car body upper plate 347 (corresponding to the car body lower plate 48) to the front-rear outside X1. Therefore, since the cross-sectional change at the end of the car body upper plate 347 at the outer side X1 in the front-rear direction can be reduced, the stress concentration at the cross-sectional change portion can be suppressed.

  The plate joining member 373 and the end portion X1 of the car body upper plate 347 in the front-rear direction are fixed by butt welding (welded portion 373y) (corresponding to the welded portion 83y). Therefore, for example, compared with the case where the plate joining material 373 is not provided and the end X1 outside the front-rear direction of the car body upper plate 347 and the main body material 371 are fixed by fillet welding, the strength of the welded portion 373y is improved. Can be improved.

  As shown in FIG. 6, when viewed from the upper side Z1, the plate joining member 373 and the car body upper plate 347 are located outside the outer periphery of the main body member 371 (when viewed from the upper side Z1) over the entire outer periphery of the main body member 371. (Outside the main body member 371). The upper surfaces of the plate joining member 373 and the car body upper plate 347 and the entire outer periphery of the main body member 371 are fixed by welding at a welded portion 371y (corresponding to the welded portion 81y (see FIG. 3)). . Therefore, compared to a case where the welded portion 371y is not continuous over the entire outer periphery of the main body material 371 (for example, a case where the welded portion 371y is interrupted on the way), the stress generated in the welded portion 371y can be suppressed, and cracks are less likely to occur in the welded portion 371y.

(Fourth embodiment)
With reference to FIG. 8, differences between the car body 430 of the fourth embodiment and the third embodiment will be described. The car body 430 includes an upper bracket 470 having a different structure from the upper bracket 370 of the third embodiment (see FIG. 7).

  The upper bracket 470 has a structure in which the lower bracket 280 (see FIG. 5) of the second embodiment is inverted in the vertical direction Z. The upper bracket 470 includes a main body 471 (corresponding to the main body 281 (see FIG. 5) of the second embodiment) and a connecting portion 475 (corresponding to the connecting portion 285 (see FIG. 5)). The lower surface of the main body member 471 is disposed above the upper surface 347t of the upper plate 347t of the car body. Therefore, the width of the arm 25a in the vertical direction Z shown in FIG. 8 can be made larger than that in the case where the main body member 371 contacts the car body upper plate upper surface 347t as shown in FIG. When the upper bracket 470 is provided, a lower bracket 280 (see FIG. 5) similar to the second embodiment may be provided.

(Modification)
The above embodiment may be variously modified. For example, constituent elements of different embodiments may be combined. For example, the arrangement and shape of each component may be changed. For example, the number of components may be changed, and some of the components may not be provided.

  For example, the car body lower plate 48 and the lower bracket 80 shown in FIG. 4 may be integrally (continuously) configured. For example, the fixing of each member may be a mechanical fixing (such as a bolt) or a fixing with an adhesive. For example, at least one of the welded portion 81y and the welded portion 83y may be replaced with at least one of mechanical fixing (such as a bolt) and fixing with an adhesive.

  For example, a recess and a protrusion having the same configuration (structure and shape) as the car body upper plate recess 347a and the car body upper plate protrusion 347b shown in FIG. 6 may be provided on the car body lower plate 48 shown in FIG. Good. In this case, the recess provided in the car body lower plate 48 is configured so that the car body lower plate 48 and the arm 25a do not interfere with each other. In addition, the protrusions provided on the car body lower plate 48 suppress the concentration of stress in the vicinity of the X1 end of the car body lower plate 48 in the front-rear direction, thereby suppressing the bending stress of the lower bracket 80 in the vertical direction Z.

DESCRIPTION OF SYMBOLS 1 Construction machine 25 Jack-up device 25a Arm 25c Cylinder 30, 230, 330, 430 Car body 40 Car body main body 47, 347 Car body upper plate 48 Car body lower plate 60 Bracket 70, 370, 470 Upper bracket 80, 280 Lower side Bracket 81, 281 Body material 81a Overlap portion 81b Body material outer portion 83 Plate joining material X1 Front / rear outside

Claims (6)

A car body of a construction machine to which an arm supporting a cylinder of a jack-up device is attached,
A car body and
A bracket protruding outward in the front-rear direction from the car body body and to which the arm is attached;
With
The car body body is
A car body upper plate constituting an upper surface of the car body main body,
A car body lower plate constituting a bottom surface of the car body main body,
With
The bracket is
An upper bracket provided on the car body upper plate,
A lower bracket provided on the car body lower plate and vertically opposed to the upper bracket,
With
The upper surface of the lower bracket is arranged below the upper surface of the car body lower plate,
The lower surface of the lower bracket is disposed below the lower surface of the car body lower plate ,
The lower bracket is a member separate from the car body lower plate,
The lower bracket extends parallel to the lower surface of the car body lower plate, is disposed so as to overlap the lower surface of the car body lower plate, and has an overlapping portion fixed to the lower surface of the car body lower plate.
Of the lower bracket, a portion outward in the front-rear direction with respect to the car body lower plate,
An outer portion of a main body material arranged below the lower surface of the car body lower plate,
A plate splicing member disposed between the outer side portion of the main body material and the arm in the up-down direction and extending outward in the front-rear direction from the front-rear outer surface of the car body lower plate,
With
The body material outer portion is integrally formed continuously with the overlapping portion in the front-rear direction,
The main body material outer portion and the overlapping portion constitute a main body material,
When viewed from below, the plate joining material and the car body lower plate protrude outward from the outer periphery of the main body material over the entire outer periphery of the main body material,
The lower surface of each of the plate joining material and the car body lower plate, and the entire periphery of the outer periphery of the main body material are fixed by welding.
Car body for construction machinery. A car body of a construction machine to which an arm supporting a cylinder of a jack-up device is attached,
A car body and
A bracket protruding outward in the front-rear direction from the car body body and to which the arm is attached;
With
The car body body is
A car body upper plate constituting an upper surface of the car body main body,
A car body lower plate constituting a bottom surface of the car body main body,
With
The bracket is
An upper bracket provided on the car body upper plate,
A lower bracket provided on the car body lower plate and vertically opposed to the upper bracket,
With
The upper surface of the lower bracket is arranged below the upper surface of the car body lower plate,
The lower surface of the lower bracket is disposed below the lower surface of the car body lower plate ,
The lower bracket is a member separate from the car body lower plate, and is fixed to a lower surface of the car body lower plate,
Of the lower bracket, a portion outward in the front-rear direction with respect to the car body lower plate,
An outer portion of a main body material arranged below the lower surface of the car body lower plate,
A plate splicing member disposed between the outer side portion of the main body material and the arm in the up-down direction and extending outward in the front-rear direction from the front-rear outer surface of the car body lower plate,
Comprising,
Car body for construction machinery. It is a car body of the construction machine according to claim 2 ,
The lower bracket includes an overlapping portion that extends in parallel with the lower surface of the car body lower plate, is arranged to overlap the lower surface of the car body lower plate, and is fixed to the lower surface of the car body lower plate.
Car body for construction machinery. It is a car body of the construction machine according to any one of claims 1 to 3 ,
In the lower bracket, a vertical thickness of a portion vertically opposed to the arm is thicker than a vertical thickness of the car body lower plate.
Car body for construction machinery. It is a car body of the construction machine according to any one of claims 1 to 4 ,
In the lower bracket, a vertical thickness of a portion vertically opposed to the arm is smaller than a vertical thickness of a portion of the upper bracket vertically opposed to the arm,
Car body for construction machinery. It is a car body of the construction machine according to any one of claims 1 to 5 ,
The front and rear outer ends of the car body lower plate and the plate joining material are fixed by welding.
Car body for construction machinery.

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