JP2014118224A - Device for firmly fastening counterweight - Google Patents

Abstract

PROBLEM TO BE SOLVED: To restrain adjacent weight rows from performing behaviors different from each other, and to suppress the oscillation and fall of the weight row.SOLUTION: A first connection member 60 is inserted into a first insertion hole 36 and connected to a base weight 20. A second connection member 70 is inserted into a second insertion hole 47 and connected to the base weight 20. A third connection member 80 is arranged on a top surface of each of first and second weight rows 30 and 40, and the first and second connection members 60 and 70 are connected together. A third connection member 80 assumes a rod shape.

Description

  The present invention relates to a counterweight securing device for securing a counterweight of a crane.

  Conventionally, there is a crane provided with a counterweight (for example, Patent Document 1). The counterweight includes a base weight and a plurality of weight rows stacked on the base weight (see FIGS. 2 and 6 in the same document). The weight rows are arranged so that a plurality of weight rows are adjacent to each other (see FIGS. 2B and 2D in the same document). Moreover, each weight row | line | column was tied with the base weight using the volt | bolt etc. (it was tied). This is to prevent weights (one by one weight constituting the weight row) from scattering apart even if the crane falls.

JP 2002-284484 A

  However, the conventional counterweight has a problem that adjacent weight rows behave differently from each other (sway or tilt in different directions). In particular, at the upper part of the weight row (near the upper surface), the displacement due to the shaking or inclination of the weight row is the largest. Usually, the upper part of the weight row is a position several times higher than the height of the worker standing on the ground around the crane. An operator who has seen a heavy object at a high position swinging or tilting in a different direction may have anxiety that the weight row may fall.

  Therefore, an object of the present invention is to provide a counterweight lashing device that can suppress adjacent weight rows from being different from each other and can suppress shaking and falling of the weight rows.

  The counterweight securing device of the present invention includes a counterweight of a crane and a connecting member that secures the counterweight. The counterweight includes a base weight, a first weight row stacked on the base weight, and a second weight row stacked on the base weight and disposed adjacent to the first weight row. . The first weight row includes a first insertion hole penetrating in the vertical direction. The second weight row includes a second insertion hole penetrating in the vertical direction. The connecting member includes a first connecting member, a second connecting member, and a third connecting member. The first connecting member is inserted into the first insertion hole and coupled to the base weight. The second connecting member is inserted into the second insertion hole and coupled to the base weight. The third connecting member is a bar-like member that is disposed on the upper surface of each of the first weight row and the second weight row and connects the first connecting member and the second connecting member.

  With the configuration described above, it is possible to suppress the adjacent weight rows from being different from each other, and it is possible to suppress the weight rows from being shaken or toppled.

It is the figure which looked at the counterweight securing device from the top. It is an II arrow directional view of FIG. FIG. 3 is a sectional view taken along the line III in FIG. 1. FIG. 4 is an enlarged view around the third connecting member 80 shown in FIG. 3. It is an enlarged view of the periphery of the connecting member 50 shown in FIG. (A)-(d): It is a figure which shows the attachment procedure of the connection member 50 to the counterweight 10 shown in FIG. FIG. 9 is a diagram corresponding to FIG.

  With reference to FIGS. 1-6, the counterweight securing apparatus 1 of embodiment of this invention is demonstrated. First, the crane C provided with the counterweight lashing device 1 will be described.

  The crane C (see FIG. 1) is a construction machine for performing operations such as hanging suspended loads. The crane C includes a lower traveling body (not shown) and a turning frame F (only the vicinity of the rear end portion of the turning frame F is shown in FIG. 1). The lower traveling body is, for example, a crawler type (that is, the crane C is, for example, a crawler crane). The turning frame F is mounted on the lower traveling body so as to be rotatable with respect to the lower traveling body. An attachment (not shown) is attached to the front end of the swivel frame F. Here, the front-rear direction of the turning frame F is referred to as “front-rear direction X”. The front side in the front-rear direction X is referred to as “front side X1”, and the rear side is referred to as “rear side X2.” The lateral direction (left-right direction) of the turning frame F is defined as “lateral direction Y”. The vertical direction (vertical direction) is defined as “vertical direction Z”.

  The counterweight securing device 1 is a device that secures the counterweight 10 with a connecting member 50. The counterweight securing device 1 includes a counterweight 10 and a connecting member 50.

  The counterweight 10 is a weight for improving the lifting capacity of the crane C. The counterweight 10 is attached to the rear end portion (rear side X2 end portion) of the turning frame F. As shown in FIG. 2, the counterweight 10 includes a base weight 20, a lower end weight row 25, a first weight row 30, and a second weight row 40. The first weight row 30 and the second weight row 40 are referred to as “weight rows 30 and 40”.

  The base weight 20 is a cradle (base, tray) for the weight rows 30 and 40. As shown in FIG. 1, the base weight 20 is fixed to the rear end portion of the swivel frame F so as to protrude from the swivel frame F to the left and right (lateral sides Y). As shown in FIG. 2, the base weight 20 includes a base weight main body portion 20 a such as a rectangular plate shape and a hook portion 20 b. The base weight main body 20a includes a hook support 20a.

  The hook support part 20as is a member that supports the hook part 20b with respect to the base weight main body part 20a. The hook support portion 20as is fixed to the upper surface and the lower surface so as to connect, for example, the upper surface and the lower surface of the base weight main body 20a. When the hooking portion 20b is a pin (columnar member), the hooking portion support portion 20as (so-called pin support portion) is a plate (for example, a rectangular plate) provided with pin holes. In this case, for example, two hooking part support parts 20as support one hooking part 20b (see FIG. 1).

  The hook portion 20b is configured to be connectable to a lower coupling portion 65 (described later) of the first coupling member 60 and a lower coupling portion 75 (described later) of the second coupling member 70. The hook portion 20b is fixed to the base weight main body portion 20a (the hook portion support portion 20as). A plurality of hooks 20b are arranged inside the base weight body 20a. As shown in FIG. 1, the hooking portion 20 b has, for example, a rod shape that extends in the lateral direction Y. The hooking portion 20b is, for example, a pin (columnar member).

  As shown in FIG. 2, the lower end weight row 25 is disposed above the base weight 20 and below the weight rows 30 and 40. The lower end weight row 25 may not be provided, and the lower end weight row 25 may be two or more.

  The weight rows 30 and 40 are weights stacked (stacked and stacked) on the base weight 20. As shown in FIG. 1, the weight rows 30 and 40 are disposed on the left and right sides (both sides in the lateral direction Y) of the rear end portion of the revolving frame F.

  The weight rows 30 and 40 are not arranged behind or above the rear end portion of the swing frame F in the crane C. The reason is as follows. In order to increase the lifting capacity of the crane C, it is ideal that the counterweight 10 is disposed on the rearmost side X2 of the turning frame F. However, if the weight rows 30 and 40 are arranged behind the rear end portion of the turning frame F, the turning radius of the rear end portion (of the upper turning body) of the crane C becomes large. Further, if the weight rows 30 and 40 are arranged behind or above the rear end portion of the swivel frame F, for example, the gantry (not shown) may not be easily tilted to the rear side X2. There is a possibility that it is difficult to arrange (not shown) or the like. Therefore, in this crane C, the weight rows 30 and 40 are not arranged behind or above the rear end portion of the turning frame F.

  The reason why the counterweight 10 is divided into a plurality of columns (four columns in FIG. 1) like the weight columns 30 and 40 is as follows. If the stacked height of the weight rows 30 and 40 becomes too high, (a) a suspension (not shown) for suspending the weight rows 30 and 40 may not be removed after the weight rows 30 and 40 are stacked, and (b ) The center of gravity of the weight rows 30 and 40 may be increased, and the stability of the weight rows 30 and 40 may be deteriorated. For this reason, when the mass of the counterweight 10 needs to be increased, the plane area of the counterweight 10 is increased. However, it is not preferable to increase the size of the counterweight 10 to a size that exceeds the limit value of the mass for public road transportation. Therefore, the counterweight 10 is divided into a plurality of weight rows 30 and 40.

  The weight rows 30 and 40 are arranged on the left and right sides (both sides in the lateral direction Y) of the rear end portion of the revolving frame F. The right weight rows 30 and 40 and the left weight rows 30 and 40 are configured (arranged and formed) symmetrically in the horizontal direction Y (symmetrically with respect to a plane orthogonal to the horizontal direction Y). Hereinafter, the weight rows 30 and 40 on one side (right side) in the horizontal direction Y will be described.

  The first weight row 30 and the second weight row 40 are disposed so as to be adjacent to each other in the front-rear direction X. The first weight row 30 and the second weight row 40 may be rearranged so as to be adjacent to each other in the lateral direction Y (hereinafter, the case where they are adjacent to each other in the front-rear direction X will be described). The second weight row 40 is disposed on the rear side X2 of the first weight row 30. The first weight row 30 and the second weight row 40 are configured symmetrically in the front-rear direction X (symmetrical with respect to a plane orthogonal to the front-rear direction X). Hereinafter, the first weight row 30 will be described, and a detailed description of the second weight row 40 will be omitted.

  As shown in FIG. 2, the first weight row 30 is stacked above the front X1 portion of the base weight 20 with respect to the front-rear direction X center. As shown in FIG. 1, the first weight row 30 is disposed at the outer end in the lateral direction Y of the base weight 20. As shown in FIG. 3, the first weight row 30 includes a weight 31 and a first insertion hole 36.

  The weight 31 is a member such as a substantially rectangular parallelepiped. A plurality of weights 31 stacked are the first weight row 30. As shown in FIG. 2, the weight 31 includes a protrusion 31 a formed on the top surface of the weight 31 body and a hole 31 b formed on the bottom surface of the weight 31 body. Each of the protrusions 31a and the holes 31b is provided in plural (for example, two) in one weight 31 (see FIG. 1). By engaging the protrusion 31a and the hole 31b, the weights 31 adjacent to each other in the vertical direction Z (or the weight 31 and the lower end weight row 25) are restricted from shifting in the front-rear direction X and the horizontal direction Y ( The weights 31 and the like can be positioned). In FIG. 2, the protrusion 31 a and the hole 31 b are illustrated only for some of the weights 31 among the plurality of weights 31.

  As shown in FIG. 3, the first insertion hole 36 is a hole (through hole) into which a first connecting member 60 (described later) is inserted. The first insertion hole 36 is formed to communicate the upper surface of the first weight row 30 and the base weight 20. The first insertion hole 36 penetrates the first weight row 30 in the vertical direction Z. When the lower end weight row 25 is below the first weight row 30, the first insertion hole 36 further penetrates the lower end weight row 25 in the vertical direction Z. As shown in FIG. 1, the first insertion holes 36 are arranged (formed) at the center (substantially center) of the first weight row 30 as viewed from above. The first insertion hole 36 (inner circumference) is, for example, a rectangle as viewed from above.

  As shown in FIG. 3, the second weight row 40 includes a plurality of weights 41 and second insertion holes 47, similar to the first weight row 30. The second insertion hole 47 is a hole into which a second connecting member 70 (described later) is inserted, and penetrates the second weight row 40 (and the lower end weight row 25) in the vertical direction Z.

  The connecting member 50 (secure member) is a member that secures the weight rows 30 and 40 to the base weight 20. The connecting member 50 includes a first connecting member 60, a second connecting member 70, and a third connecting member 80.

  The first connecting member 60 and the second connecting member 70 are configured as follows. The first connecting member 60 is inserted into the first insertion hole 36 and is coupled to the base weight 20. The second connecting member 70 is inserted into the second insertion hole 47 and is coupled to the base weight 20. Each of the first connecting member 60 and the second connecting member 70 is disposed such that the longitudinal direction is the vertical direction Z. The first connecting member 60 and the second connecting member 70 are configured symmetrically in the front-rear direction X. Hereinafter, the first connecting member 60 will be described, and a detailed description of the second connecting member 70 will be omitted. The first connecting member 60 includes a main body 61, a suspension hole 63 (see FIG. 4), a lower coupling portion 65, and an upper coupling portion 66.

  The main body 61 has a rod shape. The rod-like shape is a substantially linear shape and hardly deforms (bends or stretches). The expansion and contraction due to the screwing and unscrewing of the screw is included in “almost no deformation”. The main body 61 has a plate shape, for example. The thickness direction of the plate-like main body 61 is, for example, the lateral direction Y. The main body 61 may be, for example, a long bolt (not shown). In addition, the main-body part 61 may deform | transform other than rod shape, for example, is good also as what can be bent. Specifically, the main body 61 may be formed by connecting a plurality of link members (plates), a chain, or the like.

  The suspension hole 63 (see FIG. 4) is a hole for suspending the first connecting member 60 with an auxiliary crane (not shown). The suspension hole 63 is formed at the upper end of the main body 61.

  The lower coupling portion 65 is a portion coupled to the base weight 20 as shown in FIG. The lower coupling portion 65 is a portion that is hooked by the hook portion 20b. The lower coupling portion 65 is formed at the lower end portion of the main body portion 61. The lower coupling portion 65 has, for example, a hook shape. In addition, as for the coupling | bonding of the lower side coupling | bond part 65 and the base weight 20, what is the coupling | bonding so that the 1st connection member 60 may not leave | separate from the base weight 20 when the 1st connection member 60 is pulled up. It may be done. This coupling may be performed using a pin (not shown), for example.

  The upper coupling part 66 is a part (described later) coupled to the third coupling member 80. The upper coupling portion 66 is a hole (pin hole) into which a first pin 96 (described later) can be inserted. The upper coupling portion 66 is a long hole having a longitudinal direction in the vertical direction Z (a long hole having a width in the vertical direction Z larger than the width in the horizontal direction). The upper coupling portion 66 is formed near the upper end portion of the main body portion 61. A plurality (four in FIG. 3) of upper coupling portions 66 are provided so as to be aligned in the vertical direction Z. The plurality of upper coupling portions 66 are arranged from the upper end portion of the main body portion 61 to the central portion (the central portion in the vertical direction Z).

  Similar to the first connection member 60, the second connection member 70 includes a main body portion 71, a suspension hole 73 (see FIG. 4), a lower coupling portion 75, and an upper coupling portion 77.

  The third connecting member 80 is a member that connects the first connecting member 60 and the second connecting member 70. The third connecting member 80 is disposed on the upper surfaces of the weight rows 30 and 40. The third connecting member 80 contacts the upper surfaces of the weight rows 30 and 40. The third connecting member 80 is arranged such that the direction in which the first weight row 30 and the second weight row 40 face each other (front-rear direction X) is the longitudinal direction of the third connecting member 80. As shown in FIG. 4, the third connecting member 80 includes a main body portion 81, a suspension hole 83, a first coupling portion 86, a second coupling portion 87, a first insertion portion 88, and a second insertion portion. Unit 89.

  The main body 81 has a rod shape. As described above, the rod-like shape is a substantially linear shape and hardly deforms (bends or stretches) (extension and contraction due to screwing and unscrewing of the screw is “substantially not deforming”. Including). As shown in FIG. 5, the main body 81 includes, for example, two long plates 81a and a connecting plate 81b (for example, three plates) that connects the long plates 81a. The two long plates 81a face each other in the horizontal direction Y, for example. In FIG. 5, the first weight row 30 and the second weight row 40 are indicated by two-dot chain lines in order to avoid complexity.

  As shown in FIG. 4, the suspension hole 83 is a hole for suspending the third connecting member 80 with an auxiliary crane (not shown). The suspension hole 83 is provided in the upper part of the main body 81. A plurality (two in FIG. 4) of the suspension holes 83 are provided (or one). For example, one suspension hole 83 is provided for each of the two long plates 81a.

  The 1st coupling | bond part 86 and the 2nd coupling | bond part 87 are comprised as follows. The first connecting portion 86 is a connecting portion between the first connecting member 60 and the third connecting member 80. The second connecting portion 87 is a connecting portion between the second connecting member 70 and the third connecting member 80. The first coupling portion 86 and the second coupling portion 87 are pin holes into which the first pin 96 and the second pin 97 can be inserted. The first coupling portion 86 and the second coupling portion 87 are formed at both ends in the longitudinal direction of the main body portion 81. The distance between the first coupling portion 86 and the second coupling portion 87 is constant.

  The 1st insertion part 88 and the 2nd insertion part 89 are comprised as follows. The first insertion part 88 is inserted into the first insertion hole 36 of the first weight row 30. The second insertion part 89 is inserted into the second insertion hole 47 of the second weight row 40. The first insertion part 88 and the second insertion part 89 are formed at both ends in the longitudinal direction of the main body part 81. The first insertion part 88 and the second insertion part 89 are symmetrical in the front-rear direction X. Hereinafter, the first insertion unit 88 will be described, and the description of the second insertion unit 89 will be omitted.

  The first insertion portion 88 is configured so as to be hooked into the first insertion hole 36. The first insertion part 88 protrudes below the first coupling part 86. The first insertion part 88 projects so as to be orthogonal to the longitudinal direction of the main body part 81. As shown in FIG. 5, the width W88 of the first insertion portion 88 in the lateral direction Y is substantially the same as the width W36 of the first insertion hole 36 in the lateral direction Y. In order to suppress the movement (backlash) of the first insertion portion 88 in the lateral direction Y with respect to the first insertion hole 36, it is preferable that the size of the width W88 with respect to the width W36 is larger (wider). The size of the width W88 with respect to the width W36 is, for example, 70% or more, preferably 80% or more, 90% or more, or 95% or more.

  The first pin 96 and the second pin 97 are configured as follows. As shown in FIG. 4, the first pin 96 is a pin that couples the first coupling member 60 and the third coupling member 80, and is inserted into the upper coupling portion 66 and the first coupling portion 86. The second pin 97 is a pin that couples the second coupling member 70 and the third coupling member 80, and is inserted into the upper coupling portion 77 and the second coupling portion 87. In addition, a pin may not be used for the connection between the first connection member 60 and the third connection member 80 or the connection between the second connection member 70 and the third connection member 80. For example, the coupling may be a bolt and a nut.

(Attaching method of connecting member 50)
Next, a method of attaching the connecting member 50 to the counterweight 10 shown in FIG. 3 will be described mainly with reference to FIGS. 6 (a) to 6 (d). This attachment method includes the step of arranging the third connecting member 80, the step of arranging the first connecting member 60, the step of connecting the first connecting member 60 and the third connecting member 80, and the second connecting member 70. And a step of performing the arrangement and combination of the above. Hereafter, each process is demonstrated along a procedure (The procedure of an operation | work may be changed suitably).

(Arrangement of the third connecting member 80)
The 3rd connection member 80 shown to Fig.6 (a) is arrange | positioned as follows. The third connecting member 80 is lifted by an auxiliary crane (not shown) using a suspension hole 83 (see FIG. 4), and is disposed (installed) on the upper surfaces of the weight rows 30 and 40. As shown in FIG. 4, the first insertion part 88 and the second insertion part 89 are inserted into the first insertion hole 36 and the second insertion hole 47.

(Arrangement of the first connecting member 60)
The 1st connection member 60 shown to Fig.6 (a) is arrange | positioned as follows.
(1) The first connecting member 60 is lifted by an auxiliary crane (not shown) using a suspension hole 63 (see FIG. 4) and inserted into the first insertion hole 36. At this time, the first connection member 60 is inserted into the first insertion hole 36 while the end portion of the front side X1 of the first connection member 60 is in contact with the inner surface of the front side X1 of the first insertion hole 36. At this time, the first connecting member 60 is inserted between the two long plates 81a of the third connecting member 80 shown in FIG.
(2) As shown in FIG. 6B, the first connecting member 60 is inserted until the lower coupling portion 65 is positioned beside to the lower side of the hooking portion 20b. Prior to this time, the hooking portion 20b is attached (fixed) to the hooking portion support portion 20as (see FIGS. 2 and 3).
(3) As shown in FIG. 6C, the first connecting member 60 is moved to the rear side X2.
(4) As shown in FIG.6 (d), the 1st connection member 60 is lifted up. As a result, the lower coupling portion 65 is hooked on the hooking portion 20b.

(Combination of the first connecting member 60 and the third connecting member 80)
As shown in FIGS. 4 and 5, the first pin 96 is connected to the upper coupling portion 66 (see FIG. 4) of the first coupling member 60 and the first coupling portion 86 (see FIG. 4) of the third coupling member 80. Is inserted. Thereby, the 1st connection member 60 and the 3rd connection member 80 are couple | bonded.

(Arrangement and coupling of second connecting member 70)
Similar to the arrangement procedure of the first connecting member 60 shown in FIGS. 6A to 6C, as shown in FIG. 3, the lower connecting portion 75 of the second connecting member 70 is hooked on the hooking portion 20b. It is hung. Further, as shown in FIG. 4, the second pin 97 is inserted into the upper coupling portion 77 of the second coupling member 70 and the second coupling portion 87 of the third coupling member 80.

  Through the above steps, as shown in FIG. 3, the first connection member 60, the second connection member 70, and the third connection member 80 are connected to the base weight 20. As a result, the weight rows 30 and 40 are secured to the base weight 20. As a result, the movement of the base weight 20 above the weight rows 30 and 40 is restricted. Further, the movement of the upper surface of the second weight row 40 in the front-rear direction X with respect to the upper surface of the first weight row 30 is restricted (details will be described later).

(Effect 1)
Next, the effect of the counterweight securing device 1 shown in FIG. 1 will be described. The counterweight securing device 1 includes the counterweight 10 of the crane C and a connecting member 50 that secures the counterweight 10. As shown in FIG. 2, the counterweight 10 includes a base weight 20, a first weight row 30, and a second weight row 40. The first weight row 30 is stacked on the base weight 20. The second weight row 40 is stacked on the base weight 20 and is disposed adjacent to the first weight row 30. As shown in FIG. 3, the first weight row 30 includes a first insertion hole 36 that penetrates in the vertical direction Z. The second weight row 40 includes a second insertion hole 47 that penetrates in the vertical direction Z. The connecting member 50 includes a first connecting member 60, a second connecting member 70, and a third connecting member 80.
[Configuration 1-1] The first connecting member 60 is inserted into the first insertion hole 36 and coupled to the base weight 20.
[Configuration 1-2] The second connecting member 70 is inserted into the second insertion hole 47 and coupled to the base weight 20.
[Configuration 1-3] The third connecting member 80 is disposed on the upper surface of each of the first weight row 30 and the second weight row 40, and connects the first connecting member 60 and the second connecting member 70.
[Configuration 1-4] The third connecting member 80 has a rod shape.

(Effect 1-1: Suppression of different behaviors of weight rows 30 and 40)
The counterweight lashing device 1 includes [Configuration 1-1], [Configuration 1-2], and [Configuration 1-3]. Therefore, the first weight row 30 and the second weight row 40 adjacent to each other are secured to the base weight 20 by the connecting member 50. Therefore, it can suppress that the 1st weight row | line | column 30 and the 2nd weight row | line | column 40 which mutually adjoin each behave differently (it shakes or inclines in the direction of disjoint). As a result, anxiety of workers around the crane C can be suppressed.
Further, the third connecting member 80 has a rod shape (the above [Configuration 1-4]). Therefore, the weight rows 30 and 40 can be secured more securely than when the third connecting member 80 is a member that can be bent easily (for example, a chain or the like).

The details of the above “Effect 1-1” are as follows. If the first weight row 30 and the second weight row 40 are separately secured to the base weight 20, the following operations (1) and (2) are applied to the weight rows 30 and 40, etc. There is a problem that occurs.
(1) As shown in FIG. 2, the base weight 20 has a deflection due to the mass of the first weight row 30 (referred to as “deflection δ1”) and a deflection due to the mass of the second weight row 40 (“deflection δ2”). ) Occurs. For example, when the first weight row 30 is arranged on the front side X1 of the base weight 20 and the second weight row 40 is arranged on the rear side X2, the deflection δ1 and the deflection δ2 occur in the directions of the arrows shown in FIG. As a result, the first weight row 30 is inclined to protrude to the front side X1 as it goes up, while the second weight row 40 is inclined to protrude to the rear side X2 as it goes up. In this way, the weight rows 30 and 40 are inclined in different directions (separate directions).
(2) The counterweight 10 is vibrated by traveling or turning the crane C (see FIG. 1). As a result, for example, when the first weight row 30 is moved to the front side X1, the second weight row 40 is moved to the rear side X2. In this way, the weight rows 30 and 40 are swung in different directions (in different directions).
On the other hand, since the counterweight securing device 1 includes the above [Configuration 1-1], [Configuration 1-2], and [Configuration 1-3], the first weight row 30 and the second weight row 40 have different behaviors. Can be suppressed.

(Effect 1-2: Suppression of shaking and falling of weight rows 30 and 40)
The counterweight lashing device 1 includes [Configuration 1-1], [Configuration 1-2], and [Configuration 1-3]. Therefore, the first weight row 30 and the second weight row 40 are integrally secured. Therefore, the shaking and falling of the weight rows 30 and 40 can be suppressed.

The details of the above “Effect 1-2” are as follows.
As described above, since the weight rows 30 and 40 are integrally secured, the first weight row 30 (or the second weight row 40) alone can be prevented from falling or shaking. More specifically, even if the first weight row 30 is about to fall, the first weight row 30 is pulled to the second weight row 40 via the connecting member 50. Therefore, the first weight row 30 alone cannot fall over or shake.
Moreover, since the weight row | line 30 * 40 is tied together as mentioned above, the fall and shaking as weight row | line | column 30 * 40 integral can be suppressed. More specifically, in comparison with the distance between the fall fulcrum and the center of gravity when the first weight row 30 or the second weight row 40 is about to fall alone, the fall fulcrum when the entire weight row 30 or 40 is about to fall Increases the distance to the center of gravity. Therefore, it is possible to prevent the weight rows 30 and 40 as a whole from falling and shaking.

(Effect 2)
As shown in FIG. 3, the 1st connection member 60 and the 2nd connection member 70 are rod-shaped.
Therefore, the weight rows 30 and 40 can be more securely secured to the base weight 20 than when the first connecting member 60 and the second connecting member 70 are members that can be bent easily (for example, chains).

(Effect 3)
As shown in FIG. 4, the third connecting member 80 includes a first insertion portion 88 that is inserted into the first insertion hole 36 and a second insertion portion 89 that is inserted into the second insertion hole 47. .
In this configuration, the movement of the weight rows 30 and 40 in the direction in which the first insertion hole 36 and the second insertion hole 47 are separated can be restricted by the first insertion portion 88 and the second insertion portion 89. As a result, the weight rows 30 and 40 can be secured more securely.
Further, when the third connecting member 80 is disposed on the upper surface of the weight rows 30 and 40 (see FIG. 6A), the first insertion portion 88 is inserted into the first insertion hole 36, and the second insertion is performed. By inserting the second insertion part 89 into the hole 47, the third connecting member 80 can be easily arranged at an appropriate position.

(Other effects 1)
As shown in FIG. 3, at least one of the upper coupling portion 66 and the upper coupling portion 77 is a long hole having a longitudinal direction in the up-down direction Z (hereinafter referred to as an operation by the configuration provided in the first connecting member 60, Since the operation by the configuration of the two connecting members 70 is the same, only the operation by the configuration of the first connecting member 60 will be described.
Therefore, even if the upper coupling portion 66 and the first coupling portion 86 are displaced in the vertical direction Z, the upper coupling portion 66 and the first coupling portion 86 can be easily coupled.

(Other effects 2)
A plurality of upper coupling portions 66 are formed in the main body portion 61 so as to be aligned in the vertical direction Z.
Therefore, even if the number of weight rows 30 and 40 stacked on the base weight 20 changes, the upper coupling portion 66 and the first coupling portion 86 can be easily coupled.

(Modification)
With reference to FIG. 7, the difference with the said embodiment is demonstrated about the 3rd connection member 180 of the counterweight securing apparatus 101 of a modification. In the third connection member 80 of the counterweight securing device 1 shown in FIG. 3, the distance between the first coupling portion 86 and the second coupling portion 87 is constant (almost constant). However, the third connecting member 180 of the counterweight securing device 101 shown in FIG. 7 includes a length adjusting mechanism 181 that can change the distance between the first connecting portion 86 and the second connecting portion 87. Hereinafter, the difference will be further described.

  The length adjustment mechanism 181 is a mechanism that can adjust the length (interval, distance) between the first coupling portion 86 and the second coupling portion 87 with a screw. Specifically, for example, the length adjusting mechanism 181 includes a bolt fixed to the first coupling portion 86 and a nut fastened to the bolt and fixed to the second coupling portion 87. Things. Further, for example, the length adjusting mechanism 181 may be capable of adjusting the lengths of the first coupling portion 86 and the second coupling portion 87 using a turnbuckle (not shown) or the like. In addition, you may change suitably the combination of fixation and fastening of the 1st coupling | bond part 86, the 2nd coupling | bond part 87, a volt | bolt, and a nut.

(Effect 4)
Next, the effect of the counterweight lashing device 101 according to the modification will be described. The third connecting member 180 is a first connecting portion 86 that is a connecting portion between the first connecting member 60 and the third connecting member 180, and a second connecting portion that is a connecting portion between the second connecting member 70 and the third connecting member 180. A coupling portion 87, and a length adjustment mechanism 181 capable of adjusting the lengths of the first coupling portion 86 and the second coupling portion 87 with screws are provided.

  In the above configuration, the lengths of the first coupling portion 86 and the second coupling portion 87 can be adjusted by the length adjustment mechanism 181. Here, when the distance between the first weight row 30 and the second weight row 40 changes, the distance between the first connection member 60 and the second connection member 70 changes. Even in this case, if the lengths of the first coupling portion 86 and the second coupling portion 87 are adjusted by the length adjustment mechanism 181, the first coupling member 60, the second coupling member 70, and the third coupling member 180 are connected. Can be combined reliably. As a result, the weight rows 30 and 40 can be more securely secured.

(Other variations)
The above embodiment can be variously modified. For example, the number and arrangement of the weight rows 30 and 40 can be changed as appropriate.
(A) For example, in the above embodiment, as shown in FIG. 1, two weight rows (first weight row 30 and the like) are provided on each side Y side of the turning frame F (four in total). However, three or more weight rows (first weight row 30 or the like) may be provided on one side in the lateral direction Y of the turning frame F. Specifically, for example, a weight row (not shown) may be provided on the front side X1 of the first weight row 30, the rear side X2 of the second weight row 40, or the lateral direction Y outside of the weight rows 30 and 40. .
(B) Further, for example, in the above embodiment, the weight rows 30 and 40 are not provided behind or above the rear end portion of the turning frame F, but the weight row 30 is provided behind or above the rear end portion of the turning frame F. -40 may be provided.

DESCRIPTION OF SYMBOLS 1,101 Counterweight securing apparatus 10 Counterweight 15 Base weight 30 1st weight row 35 1st insertion hole 40 2nd weight row 46 2nd insertion hole 50 Connection member 60 1st connection member 70 2nd connection member 80 , 180 Third connecting member 85 First insertion portion 86 Second insertion portion 87 First coupling portion 88 Second coupling portion 181 Length adjusting mechanism

Claims (4)

The crane counterweight,
A connecting member for securing the counterweight;
With
The counterweight is
Base weight,
A first weight row stacked on the base weight;
A second weight row stacked on the base weight and disposed adjacent to the first weight row;
With
The first weight row includes a first insertion hole penetrating in a vertical direction,
The second weight row includes a second insertion hole penetrating in the vertical direction,
The connecting member is
A first connecting member inserted into the first insertion hole and coupled to the base weight;
A second connecting member inserted into the second insertion hole and coupled to the base weight;
A rod-like third connecting member that is disposed on an upper surface of each of the first weight row and the second weight row and connects the first connecting member and the second connecting member;
A counterweight lashing device comprising: The first connecting member and the second connecting member are rod-shaped,
The counterweight lashing device according to claim 1. The third connecting member is
A first insertion part to be inserted into the first insertion hole;
A second insertion part to be inserted into the second insertion hole;
The counterweight lashing device according to claim 1, comprising: The third connecting member is
A first coupling portion that is a coupling portion between the first coupling member and the third coupling member;
A second coupling portion that is a coupling portion between the second coupling member and the third coupling member;
A length adjustment mechanism capable of adjusting the lengths of the first coupling portion and the second coupling portion with screws;
A counterweight securing device according to any one of claims 1 to 3.

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