JP3183188U - Weight block structure - Google Patents

Abstract

Provided is a weight block structure capable of changing and adjusting the weight when fixing a support body such as a solar battery panel.
In a weight block structure X, a plurality of weight blocks Y are stacked and configured by, for example, first to third block groups. The plurality of weight blocks includes a positioning protrusion 2 and a plurality of positioning lateral grooves 3. In the first-stage block group Z1, the positioning protrusions are arranged in parallel, and a plurality of weight blocks are placed on the column body. In the second-stage block group Z2, the positioning projections of the respective weight blocks one step below are fitted into the plurality of positioning lateral grooves, and the plurality of weight blocks are stacked across the respective weight blocks one step below. In the third-stage uppermost block group Z3, the positioning protrusions of the respective weight blocks one step below the uppermost step are fitted into the plurality of positioning lateral grooves, and one or more weight blocks are placed one step lower than the uppermost step. A weight block structure is formed by stacking over each weight block.
[Selection] Figure 1

Description

  The present invention relates to a weight block structure that is placed on a support body that supports a supported object such as a solar battery panel and fixes the support body.

  As a technique for fixing a column body of a solar cell panel, Patent Literature 1 discloses a photovoltaic power generation array mount. This photovoltaic power generation array frame supports a solar panel with a plurality of support columns, and fixes each support column to a plurality of foundation blocks. Each foundation block is placed on the roof surface and fixes each column (solar panel) to the roof.

JP 2011-911166 A

  However, in patent document 1, since the some support | pillar is being fixed to the foundation block, the weight of a foundation block cannot be changed and adjusted easily.

An object of the present invention is to provide a weight block structure in which a weight can be easily changed and adjusted by stacking a plurality of weight blocks.
It is another object of the present invention to provide a weight block structure that does not easily fall over even when a plurality of weight blocks are stacked.

  According to the first aspect of the present invention, in a weight block structure that is placed on a support body that supports a supported object such as a solar battery panel and fixes the support body, a plurality of weight blocks are stacked to form a multistage block group. A weight block structure in which each stage block group is formed of one or a plurality of weight blocks, each weight block being formed in a rectangular cross section and forming a rectangular outer edge; A long block body having a front and back plane, a positioning protrusion that is formed to project from the upper plane and extends in the longitudinal direction of the long block body between the front and back planes, and an opening is formed in the lower plane, and the longitudinal direction And a plurality of positioning lateral grooves that extend in the width direction of the long block main body and open to the left and right planes, and the first-stage block group includes the positioning block. A plurality of weight blocks are mounted on the support body from the lower plane, with a plurality of weight blocks arranged in parallel, and each stage block group excluding the first stage and the uppermost stage includes a plurality of the positioning blocks. In the horizontal groove, the positioning projection of each weight block one step below each step is fitted, and a plurality of weight blocks are stacked across each weight block below the one step, and the uppermost block group is In each of the plurality of positioning lateral grooves, the positioning projections of the respective weight blocks one step below the uppermost step are fitted, and one or more weight blocks are stacked across the respective weight blocks one step below the first step. It is a weight block structure characterized by comprising.

  According to a second aspect of the present invention, the positioning protrusion is formed to protrude in the center in the width direction of the long block main body, and the positioning lateral grooves are symmetrically arranged on both sides of the center in the longitudinal direction, and the horizontal plane 2. The weight block structure according to claim 1, wherein the weight block structures are arranged side by side with a groove interval exceeding a block width therebetween.

  According to a third aspect of the present invention, each of the weight blocks is formed in the lower plane, extends in the longitudinal direction of the long block body, and opens in the front-rear plane perpendicular to the positioning lateral grooves. The weight block structure according to claim 1, further comprising a longitudinal groove.

  According to a fourth aspect of the present invention, there is provided a weight block structure in which a plurality of weight blocks are stacked to form a multi-stage block group, and the block group at each stage is formed of one or a plurality of weight blocks. The block has a long block main body, a protruding protrusion formed on the long block main body and extending in a longitudinal direction of the long block main body, and an opening formed in the long block main body facing the positioning protrusion. And a plurality of positioning lateral grooves penetrating the long block main body in the width direction perpendicular to the longitudinal direction and arranged in parallel in the longitudinal direction at intervals, the first stage block group Is configured by arranging the positioning protrusions in parallel and arranging a plurality of weight blocks in parallel, except for the first step and the uppermost step, and the step block group is one step below the plurality of positioning lateral grooves. Each weight The positioning protrusions of the rack are fitted and a plurality of weight blocks are stacked across the weight blocks one step below, and the uppermost block group is formed in the plurality of positioning lateral grooves from the uppermost step. A weight block structure in which the positioning protrusions of each weight block one step below are fitted and one or a plurality of weight blocks are stacked across each weight block one step below the uppermost step Is the body.

According to the first aspect of the present invention, a plurality of weight blocks are stacked to form a multi-stage block group, and therefore, a weight lock structure can be selected by appropriately selecting the number of block groups and the number of weight blocks forming each block group. You can change and adjust the weight of your body.
In the first aspect, since the weight blocks of each stage block group are stacked orthogonally to each other, even if a plurality of weight blocks are stacked to form a multistage block group, the structure does not fall easily.
Further, in the stage block group excluding the first stage and the uppermost stage, each weight block is fitted with the positioning protrusion of each lower weight block in each positioning lateral groove, and the positioning protrusion is further moved to each weight of the upper stage. Since it fits in each positioning lateral groove of a block, it becomes a structure which cannot move to a longitudinal direction and the width direction.
As a result, the stage block group excluding the first stage and the uppermost stage allows each weight block to be moved between each lower weight block and each upper weight block by the cooperation of the positioning protrusion and each positioning lateral groove. The weight block structure can be made difficult to fall down.
In the first aspect, in the first stage block group, the plurality of positioning lateral grooves penetrate the weight lock structure in the width direction of the long block body.
Thereby, even if a weight block structure receives a wind, it can escape a wind outside through each positioning lateral groove, and becomes a structure which cannot fall easily with a wind force.
In this way, according to the first aspect, the weight of the weight block structure can be changed and adjusted, and the weight block small structure that is not easily tilted can be configured. Therefore, the support body can be fixed under the optimum conditions.

According to the second aspect of the present invention, the positioning projection is arranged in the center in the width direction, and the positioning lateral grooves are arranged in parallel with a groove interval exceeding the block width, so that a plurality of weight blocks are stacked to form a multi-stage block group. Then, a ventilation gap can be formed between the weight blocks.
Since the weight blocks of each stage block group are stacked orthogonally to each other, the ventilation gaps of each stage block group are also communicated orthogonally to each other.
Thereby, even if a weight block structure receives a wind, it can escape a wind outside through the ventilation gap of each step block group, and becomes a structure which is hard to fall down with a wind force.

According to a third aspect of the present invention, in the first stage block group, the longitudinal groove of each weight block penetrates the front and back planes of the weight block structure in the longitudinal direction.
Thereby, even if a weight block structure receives wind, it can escape a wind outside through each vertical groove, and becomes a structure which is hard to fall down by wind force.

In claim 4 according to the present invention, since a plurality of weight blocks are stacked to form a multi-stage block group, the weight lock structure can be selected by appropriately selecting the number of block groups and the number of weight blocks forming each block group. You can change and adjust the weight of your body.
In the first aspect, since the weight blocks of each stage block group are stacked orthogonally to each other, even if a plurality of weight blocks are stacked to form a multistage block group, the structure does not fall easily.
Further, in the stage block group excluding the first stage and the uppermost stage, each weight block is fitted with the positioning protrusion of each lower weight block in each positioning lateral groove, and the positioning protrusion is further moved to each weight of the upper stage. Since it fits in each positioning lateral groove of a block, it becomes a structure which cannot move to a longitudinal direction and the width direction.
As a result, the stage block group excluding the first stage and the uppermost stage allows each weight block to be moved between each lower weight block and each upper weight block by the cooperation of the positioning protrusion and each positioning lateral groove. The weight block structure can be made difficult to fall down.
According to a fourth aspect of the present invention, in the first stage block group, the plurality of positioning lateral grooves penetrate the weight lock structure in the width direction of the long block body.
Thereby, even if a weight block structure receives a wind, it can escape a wind outside through each positioning lateral groove, and becomes a structure which cannot fall easily with a wind force.

It is a perspective view which shows a weight block structure and each step block group. It is a principal part enlarged front view of FIG. It is a principal part expansion right view of FIG. It is a principal part enlarged view which shows insertion of a positioning lateral groove and a positioning protrusion. It is a perspective view which shows a weight block. It is a figure which shows a weight block, Comprising: (a) is a front view, (b) is a top view. It is a figure which shows a weight block, Comprising: (a) is a bottom view, (b) is a right view. It is a figure which shows a weight block, Comprising: (a) is AA sectional drawing of FIG.6 (b) shape | molded with concrete or a metal, (b) is A of FIG.3 (b) shape | molded with resin and concrete. It is -A sectional drawing. It is a figure which shows a weight block structure, Comprising: It is a front view which makes groove space the same as a block width. It is the perspective view which applied the weight block structure to the support body which supports a solar cell panel (application example 1). It is a B arrow enlarged view of FIG. It is the perspective view which applied the weight block structure to the support | pillar body which supports a solar cell panel (application example 2). It is C arrow enlarged view of FIG.

  A weight block structure according to the present invention will be described with reference to FIGS.

<Weight block structure>
1 to 9, the weight block structure (X) stacks a plurality of weight blocks (Y) to form a multistage block group (Z).
The multistage block group (Z) includes, for example, a first stage block group (Z1), a second stage block group (Z2), and a third stage block group (Z3).
The third block group (Z3) is the uppermost block group (hereinafter also referred to as “uppermost block group Z3”).
The second stage block group (Z2) is a stage block group excluding the first stage and the upper stage.
The multi-stage block group (Z) is not limited to three stages, but two stages, four stages, five stages,..., N stages [N = 2, 3, 4,... N (N: integer)]

The first and second stage block groups (Z1) and (Z2) are formed of a plurality (three) of weight blocks (Y).
The third-stage block group (Z3) is formed of one or plural (three) weight blocks (Y).

<Weight block>
5 to 8, each weight block (Y) includes a long block body (1), positioning protrusions (2), a plurality (three) of positioning lateral grooves (3), a longitudinal groove (5) and a plurality of (2 ) Handle hole (6).

  As shown in FIG. 8A, each weight block (Y) is formed into a solid body, and is formed of, for example, concrete or a metal such as iron or aluminum.

Further, as shown in FIG. 8B, each weight block (Y) has a positioning projection (2), positioning lateral grooves (3), vertical grooves (5) and handle holes (6) integrated with a synthetic resin. The hollow body (Y1) is formed, and the hollow body (Y1) is filled with concrete.
Thereby, since each weight block (Y) coat | covers concrete with a synthetic resin, it can suppress deterioration of concrete.

As shown in FIGS. 5 to 8, the long block body (1) is formed in a rectangular parallelepiped having a rectangular cross section.
The long block body (1) has upper and lower planes (1A) and (1B), left and right planes (1C) and (1D), and front and rear planes (1E) and (1F), and each plane (1A) to (1F) ) To form a rectangular outer edge (1X) [each plane of a rectangular parallelepiped].

As shown in FIGS. 5 to 8, the positioning protrusion (2) is formed to protrude from the upper plane (1A) of the long block main body (1), and the long block main body (1E) is formed between the front and rear planes (1F). It extends in the longitudinal direction (N) of (1).
The positioning protrusion (2) is arranged at the center in the width direction of the long block body (1) in the width direction (H) [see FIGS. 5 and 6 (a)]. The width direction (H) is a direction orthogonal to the longitudinal direction (N).

Further, the positioning protrusion (2) is formed, for example, in a trapezoidal cross section and protrudes upward (L1) in the height direction (L) from the upper plane (1A). The height direction (L1) is a direction orthogonal to the longitudinal direction (N) and the width direction (H).
The cross-sectional trapezoid of the positioning protrusion (2) has left and right side planes (2A) and (2B). The left plane (2A) is continuous to the upper plane (1A) between the width direction center line (a) and the left plane (1C), and is inclined toward the width direction center line (a).
The right plane (2B) is continuous with the upper plane (1A) between the width direction center line (a) and the right plane (1C), and is inclined toward the width direction center line (a).

As shown in FIGS. 5 to 8, the plurality of positioning lateral grooves (3) are formed in the lower plane (1B) of the long block body (1) so as to face the positioning protrusion (2).
The plurality of positioning lateral grooves (3) includes, for example, a center / positioning lateral groove (3), a front side / positioning lateral groove (3), and a rear side / positioning lateral groove (3).
The center / positioning lateral groove (3) is disposed at the center in the longitudinal direction (N).
The front and rear and positioning lateral grooves (3), (3) are symmetrically arranged on both sides of the center in the longitudinal direction (N).
Each positioning lateral groove (3) is juxtaposed with a groove interval (G) in the longitudinal direction (N). The groove interval (G) is the interval between the longitudinal center lines (b) of the positioning lateral grooves (3) and exceeds the block width (h) between the left and right planes (1C) and (1D).
The front and rear side / positioning lateral grooves (3), (3) are juxtaposed with a double groove interval (G) exceeding the block width (h).
Each positioning lateral groove (3) penetrates the long block body (1) in the width direction (H). Each positioning lateral groove (3) extends in the width direction (H) and opens in the left and right planes (1C) and (1D).

Each positioning lateral groove (3) is formed in a trapezoidal cross section, for example, and has the same shape (trapezoid) as the positioning projection (2). The trapezoidal cross section of each positioning lateral groove (3) has left and right side grooves (3A) and (3B).
In the front side / positioning lateral groove (3), the left groove side surface (3A) is continuous to the lower plane 1B on the front plane 1E side, and is inclined to the rear plane (1F) side while extending to the upper plane (1A) side. The left groove side surface (3B) is continuous with the lower plane (1B) on the center / positioning lateral groove (3) side, and is inclined toward the front plane (1E) side while extending to the upper plane (1A) side.
In the center / positioning lateral groove (3), the left-side groove side surface (3A) is continuous with the lower plane 1B on the front side / positioning lateral groove (3) side, and extends to the upper plane (1A) side while extending to the rear plane (1F) side. Be inclined. The right groove side surface (3B) is continuous with the lower plane (1B) on the rear side / positioning lateral groove (3) side, and is inclined toward the front plane (1E) side while extending to the upper plane (1A) side.
In the rear side / positioning lateral groove (3), the left side groove side surface (3A) is continuous with the lower plane (1B) on the center / positioning lateral groove (3) side, and extends to the upper plane (1A) side while the rear plane (1F ) Tilted to the side. The right groove side surface (3B) is continuous with the lower plane (1B) on the rear plane (1F) side, and is inclined to the front plane (1E) side while extending to the upper plane (1A) side.

As shown in FIGS. 5 to 8, the longitudinal groove (5) has an opening formed in the lower plane (1B), and the longitudinal direction (N) of the long block body (1) between the front and rear planes (1E) and (1F). ).
The vertical groove (5) opens in the front and rear planes (1E) and (1F) perpendicular to each positioning horizontal groove (3).
The longitudinal groove (5) is arranged at the center in the width direction (H) and extends in the longitudinal direction (N) in parallel with the positioning protrusion (2).

Moreover, the vertical groove (5) is formed in, for example, a trapezoidal cross section and has the same shape (trapezoid) as each positioning lateral groove (3).
In the longitudinal groove (5), the cross-sectional trapezoidal groove has left and right groove side surfaces (5A) and (5B). The left groove side surface (5A) is continuous with the lower plane (1B) between the width direction center line (a) and the left plane (1C), and extends to the upper plane (1A) side while extending in the width direction center line (a) side. Inclined towards. The right groove side surface (5B) is continuous to the lower plane (1B) between the width direction center line (a) and the right plane (1B), and extends to the upper plane (1A) side while extending in the width direction center line (a) side. Be inclined to.

As shown in FIGS. 5 to 8, the plurality of handle holes (6) are formed in the front and rear planes (1E) and (1F), respectively.
Each handle hole (6) is located between the positioning projection (3) and the longitudinal groove (5) in the height direction (L) of the long block body (1), and the long block body ( 1) Extend inside.

<Specific configuration of weight block structure>
Next, a specific configuration of the weight block structure (X) will be described with reference to FIGS.

1 to 3, the weight block structure (X) includes a plurality of weight blocks (Y) to form a multi-stage block group (Z). For example, the first-stage block group (Z1), It consists of a second stage block group (Z2) and a third stage block group (Z3).
In the weight block structure (X), the first-stage block group (Z) is formed, the second-stage block group (Z2) is formed on the first-stage block group (Z1), and the second-stage block group (Z) is further formed. A third-stage block group (Z3) is formed on the eye block group (Z2).

As shown in FIG. 1, the first-stage block group (Z1) is configured by arranging a plurality of (three) weight blocks (Y) in parallel with positioning protrusions (3).
Each weight block (Y) is arranged in parallel in the width direction (H) of the long block main body (1) with a groove interval (G) between the center lines (a) in the width direction of the positioning protrusions (2). .
Thus, a first ventilation gap (t) is formed between the weight blocks (Y), and the first ventilation gap (t1) is the first step in the longitudinal direction (N) of the long block body (1). It penetrates the block group (Z1).
Further, each positioning lateral groove (3) of each weight block (Y) penetrates the first block group (Z1) in the width direction (H) of the long block body (1), and further, the longitudinal groove (5). Passes through the first block group (Z1) in the longitudinal direction N of the long block body (1).
In the first stage block group (Z1), in the width direction (H) of the long block body (1), the weight blocks (Y ).
Further, an operator who loads the weight blocks (Y) can arrange the weight blocks (Y) in parallel by grasping and lifting the handle holes (6) of the weight blocks (Y).

The second-stage block group (Z1) includes a plurality of (3) positioning protrusions (2) of each weight block (Y) one step below (first stage) in a plurality of positioning lateral grooves (3). The weight blocks (Y) are stacked on the upper plane (1A) of each weight block (Y) one step below.
In the second-stage block group (Z2), each weight block (Y) has a long block body (1) arranged orthogonally to the long block body (1) of each weight block (Y) one step below. Further, each positioning lateral groove (3) of each weight block (Y) faces the positioning protrusion (2) of each weight block (Y) one step below.
In the second-stage block group (Z2), each weight block (Y) is lowered from the lower plane (1B) toward each lower-stage weight block (Y), and is placed one step lower in each positioning lateral groove (3). The positioning projections (3) of each weight block (Y) are fitted and stacked on the upper plane (1A) of each weight block (Y) one step below. At this time, in each positioning lateral groove (3) of each weight block (Y), the left and right nominal side surfaces (3A) and (B) are positioned one step down (first stage) as shown in FIG. 2) are in close contact with the left and right side surfaces (2A) and (2B). The longitudinal center line (b) of each positioning lateral groove (3) and the width direction center line (a) of the positioning projection (3) coincide.
Thereby, in the second stage block group (Z2), each weight block (Y) is a long block by the cooperation of the positioning lateral groove (3) and the lower one (first stage) positioning projection (2). The movement of the main body (1) in the longitudinal direction (N) is restricted.
Further, in the first stage block group (Z1), each weight block (Y) is a long block in cooperation with the positioning protrusion (2) and each positioning lateral groove (3) on the upper stage (second stage). The movement of the main body (1) in the width direction (H) is restricted.

Further, in the second stage block group (Z2), each weight block (Y) is slid in the longitudinal direction (N) along the positioning projection (2) of each block (Y) one stage below, and each positioning block (Y). The distance between the center lines (a) in the width direction of the protrusions (2) is defined as a groove interval (G).
Thus, a ventilation gap (t2) is formed between the weight blocks (Y), and the second ventilation gap (t2) is a second-stage block in the longitudinal direction (N) of the long block body (1). It penetrates the group (Z2). The second ventilation gap (t2) is communicated with the first ventilation gap (t1) perpendicular to the first ventilation gap (t1).
In the second stage block group (Z2), in the width direction (H) of the long block main body (1), the weight blocks (Y ).
Further, the operator can load each weight block on each weight block (Y) of the first-stage block group (Z1) by grasping and lifting each handle hole (6) of each weight block (Y). .

The uppermost block group (Z3: third-stage block group) includes positioning protrusions (2) of each weight block (Y) that are one step lower (second step) than the uppermost step in the plurality of positioning lateral grooves (3). ), And one or a plurality of weight blocks (Y) are stacked on the upper plane (1A) of each weight block (Y) one step below the uppermost level.
In the uppermost block group (Z3), each weight block (Y) has a long block body (1) from the lower plane (1B), and the long block body of each weight block (Y) one step below the uppermost stage. (1) is arranged orthogonally. Further, each positioning lateral groove (3) of each weight block (Y) is opposed to the positioning protrusion (2) of each weight block one step below the uppermost stage.
In the uppermost block group (Z3), each weight block (Y) is lowered toward each weight block (Y) one step below the uppermost step, and each step below the uppermost step is placed in each positioning lateral groove (3). The positioning projections (3) of the weight block (Y) are fitted and stacked on the upper plane (1A) of each weight block (Y) one step below the uppermost level. At this time, in each positioning lateral groove (3) of each weight block (Y), the left and right nominal side surfaces (3A) and (B) are positioned one step down (second stage) as shown in FIG. 2) are in close contact with the left and right side surfaces (2A) and (2B). Further, the longitudinal center line (b) of each positioning lateral groove (3) and the width direction center line (a) of the positioning protrusion (2) coincide with each other.
As a result, in the uppermost block group (Z3), each weight block (Y) has a long block main body in cooperation with the positioning lateral groove (3) and the lower one (second stage) positioning projection (2). The movement of (1) in the longitudinal direction (N) is restricted.
Further, in the second stage block group (Z2), each weight block (Y) is a long block in cooperation with the positioning projection (2) and each positioning lateral groove (3) one stage (second stage). The movement of the main body (1) in the width direction (H) is restricted.
As shown in FIG. 1, in the odd-stage block group including the first stage and the third stage, each weight block (Y) is stacked with the width center line (a) coincided, and the second stage In the even-numbered-stage block group including the stages, the weight blocks (Y) are stacked with the center line (a) in the width direction aligned.
Thereby, since the weight lock structure (X) can load each weight block (Y) equally, it can suppress the bias | inclination of a weight.

In the uppermost block group (Z3), each weight block (Y) is slid in the longitudinal direction (N) along the positioning projection (2) of each weight block one step below the uppermost stage, The gap between the center lines (a) in the width direction of the positioning protrusions (2) is set to the groove interval (G).
Thus, a third ventilation gap (t3) is formed between the weight blocks (Y), and the third ventilation gap (t3) is the uppermost step in the longitudinal direction (N) of the long block body (1). It penetrates the block group (Z3). The third ventilation gap (t3) communicates with the second ventilation gap (t2) perpendicular to the second ventilation gap (t). Further, the third ventilation gap (t3) communicates with the first ventilation gap (t) through the second ventilation gap (t2) in parallel with the first ventilation gap (t1).
In the uppermost block group (Z3), the number of weight blocks (Y) is appropriately selected, and each weight block (Y) is assigned to each weight block (Y) in the second block group (Z2). Can be stacked.
Further, the operator grasps and lifts each handle hole (6) of each weight block (Y), thereby lifting each weight block (Y) to each weight block (Y) of the second stage block group (Z2). Can be loaded.
Thus, the weight block structure (X) is formed by stacking the plurality of weight blocks (Y) to form the multistage block group (Z).

In addition, when the positioning protrusions (2) are fitted into the positioning lateral grooves (3) in the second stage block group (Z2) and the uppermost stage (third stage) block group (Z3), FIG. As shown, even if each positioning lateral groove (3) is displaced in the longitudinal direction (N) with respect to the positioning projection (2), the left groove side surface (3A) on one side of each positioning lateral groove (3) [or the right groove The side surface (3B)] is brought into contact with the left side surface (3B) [or the right side surface (3B)] on one side of the positioning protrusion (2).
Then, when each weight block (Y) is lowered and loaded on each weight block (Y) one step below, each positioning lateral groove (3) has a left side surface (2A) on one side of the positioning projection (3) [or right side The surface (2B)] is slid and guided obliquely while absorbing the deviation, and the positioning protrusion (2) is inserted.
Thereby, even if each positioning lateral groove (3) and positioning protrusion (2) have shifted | deviated relatively, the positioning protrusion (2) can be inserted in each positioning lateral groove (3).

When the weight block structure (X) is composed of each block group (Z1), (Z2), (Z3), the positioning protrusion (2) is one step higher in each weight block (Y) of the first-stage block group. Each weight block (Y) is moved in the width direction (H) of the long block main body (1) because it is inserted into each positioning lateral groove (3) of each weight block (Y) in the (second stage). do not do.
In each weight block (Y) of the second stage block group (Z2), each positioning lateral groove (3) is fitted with a positioning projection (3) of each weight block (Y) one step down (first stage). Therefore, it does not move in the longitudinal direction (N) of the long block body (1). Moreover, since the positioning protrusion (3) is fitted into each positioning lateral groove (3) of each weight block (Y) that is one step higher (uppermost step), the width direction (H) of the long block body (1) Do not move to.
As a result, in the stage block group (Z2) excluding the first stage and the top stage, each weight block (Y) is replaced with the weights of the first stage and the top stage block groups (Z1), (Z3). By the cooperation with the block (Y), the first weight block and the uppermost weight block (Y) are fixed.
In the uppermost block group (Z3), one weight block (Y) or two weight blocks (Y) can be stacked on each weight block (Y) one step lower than the uppermost step (second step).

In the weight block structure (X), the first to third ventilation gaps (t1), (t2), and (t3) communicate with each other and penetrate through the weight block structure (X) in the front-rear, left-right, and upper directions. .
In the first stage block group (Z1), the positioning lateral groove (3) of each weight block (Y) penetrates to the left and right of the weight block structure (X) in the width direction (H) of the long block body (1). The longitudinal groove (5) of each weight block (Y) penetrates the weight block structure (X) in the longitudinal direction (N) of the long block body (1).
As a result, even if the weight block structure (X) receives wind, the wind passes outward through the positioning lateral grooves (3), the vertical grooves (5), and the first to third ventilation gaps (t1) to (t3). It can escape and has a structure that is hard to collapse by wind power.

  Thus, in the weight block structure (X), a plurality of weight blocks (Y) can be stacked to form a multi-stage block group (Z), and the number of steps in the block group and the number of weight blocks in each block group can be selected as appropriate. Thus, the weight of the weight lock structure (Z) can be changed and adjusted.

  In the weight lock structure (X), the odd-numbered first and third-stage block groups (Z1) and (Z3) weight blocks (Y) and the even-numbered second-stage blocks. Since the weight blocks (Y) of the group (Z2) are stacked perpendicular to each other, even if a plurality of weight blocks (Y) are stacked to form a multi-stage block group (Z), the structure does not easily fall down.

  In the weight block structure (X), the cross section of the weight block is not limited to a rectangular cross section, and a polygonal cross section, a circular cross section, an elliptical cross section, or the like can be adopted.

In the weight block structure (X), as shown in FIG. 9, the groove interval (G) can be made equal to the block width (H1).
Thereby, in each step block group (Z1), (Z2), (Z3), as shown in FIG. 9, the left and right planes (1C), (D) of each weight block (Y) are brought into contact with each other. It can be stacked and has a structure that does not easily collapse due to friction between the weight blocks (y).

<Application example of weight block structure>
Next, application example 1 and application example 2 of the weight block structure (X) will be described with reference to FIGS. 10 and 13.
10 to 13, the same reference numerals as those in FIGS. 1 to 9 denote the same members or the same configuration, and thus detailed description thereof will be omitted.

<Application example 1>
In FIG. 10, the weight block structure (X) is placed on a support body (A) that supports a solar cell panel (S: supported object), and fixes the support body (A).

As shown in FIG. 10, the support (A) is a gantry that supports the solar cell panel (S), and includes a plurality of (four) columns (51) and a column frame (52). . Each strut (51) is formed of metal such as steel or aluminum alloy, for example.
The support frame (52) is formed of the same metal as each support (51), and a rectangular frame is formed by a plurality (four) of L-shaped metal members (53), and the bottom of each support (51) is formed at each corner. The side is fixed. Further, the support frame (52) is placed on the roof or the ground, and the solar cell panel (S) is installed on the roof or the ground via each support (51).
Each L-shaped metal plate (53) is formed of a vertical flat plate (53A) orthogonal to the roof or the ground and a horizontal flat plate (53B) placed on the roof or the ground.

10 and 11, a plurality of weight block structures (X) are prepared, arranged in the vicinity of each column (51), and placed on the column base frame (52).
In each weight block structure (X), as described with reference to FIGS. 1 to 4, the positioning protrusions (2) are arranged in parallel, and a plurality (three) of weight blocks (Y) are formed from the lower plane (1B). It mounts on a support | pillar body (A) and comprises a 1st step | paragraph block group (Z1).
In the first stage block group (Z1), as shown in FIGS. 10 and 11, each vertical block (Y) has an L-shape in a positioning lateral groove (3) on one end side in the longitudinal direction (N), for example. A vertical plate (53A) of the metal plate (53) is inserted. Further, in the first stage block group (Z1), each weight block (Y) is placed on the horizontal flat plate (53B) of the L-shaped metal plate (53) from the lower flat surface (1B).
Thereby, in a 1st step | paragraph block group (Z1), each weight block (Y) can fix a support body (A) using a support | pillar base frame (52). Further, each weight block (Y) can fix the columnar body (A) by inserting the vertical flat plate (53A) of the L-shaped metal plate (53) into the positioning lateral groove (3).
Subsequently, as described with reference to FIGS. 1 to 4, the second-stage block group (Z2) is configured, and the third-stage block group (Z3) is further configured.
In each weight block structure (X), the number of weight blocks (Y) and the number of stages of the block group are selected as appropriate, and the weight is adjusted to a weight that can fix the column [A: each column (51)].

  As described above, in each weight block structure (X), the weight for fixing the support (A) can be changed and adjusted, and a weight block structure that is hard to fall down can be configured. Can be fixed.

<Application example 2>
In FIG. 12, the weight block structure (X) is placed on a support (A) that supports a solar cell panel (S: supported object), and fixes the support (A).

  12 and 13, the column body (A) is composed of a plurality of (four) columns (51) and column columns (52), as in FIGS. 10 and 11, and a plurality of pedestal flat plates (52). 55). As shown in FIG. 12, each pedestal flat plate (55) is positioned in the vicinity of the left and right support columns (51) in the left-right direction (U) and extends in the front-rear direction (W). In each L-shaped metal material (53) in the front-rear direction (W), each pedestal flat plate (55) is placed on a horizontal flat plate (53B).

12 and 13, a plurality of weight block structures (X) are prepared, arranged in the vicinity of each column (51), and placed on each pedestal flat plate (55).
In each weight block structure (X), as described with reference to FIGS. 1 to 4, the positioning protrusions (2) are arranged in parallel, and a plurality (three) of weight blocks (Y) are formed from the lower plane (1B). It mounts on a support | pillar body [A: Each base flat plate (55)], and comprises a 1st step | paragraph block group (Z1).
Subsequently, as described with reference to FIGS. 1 to 4, the second-stage block group (Z2) is configured, and the third-stage block group (Z3) is further configured.
In each weight block structure (X), the number of weight blocks (Y) and the number of stages in the block group are appropriately pioneered to adjust the weight to fix each column (51).
As described above, in the weight block structure (X), the weight can be changed and adjusted, and a weight block structure that does not easily fall down can be configured. Therefore, the support body (A) can be fixed under optimum conditions.

  The weight block structure (X) is not limited to the support body (A) that supports the solar battery panel (S), and the support body that supports the advertising flag (supported object) and the laundry is supported by hanging. It is possible to fix the column body by placing it on the column body (washing).

  The present invention is most suitable for fixing a column body that supports a supported object such as a solar battery panel.

X weight block structure Z1 first stage block group Z2 second stage block group (stage block group excluding the first stage and the top stage)
Z3 3rd stage block group (top stage block group)
Y weight block 1 long block body 1A upper plane 1B lower plane 1C left plane 1D right plane 1E front plane 1F rear plane 2 positioning projection 3 positioning lateral groove

Claims (4)

In a weight block structure that is placed on a column body that supports a supported object such as a solar cell panel and fixes the column body,
A weight block structure in which a plurality of weight blocks are stacked to form a multistage block group, and each stage block group is formed of one or more weight blocks,
Each weight block is
A long block body having a vertical cross-section, a left-right plane and a front-rear plane formed in a rectangular cross-section and forming a rectangular outer edge;
A positioning protrusion formed on the upper plane and extending in the longitudinal direction of the long block body between the front and rear planes;
A plurality of positioning lateral grooves that are formed in the lower plane and are arranged side by side in the longitudinal direction at intervals, and that extend in the width direction of the long block body and open in the left and right planes;
Including
The first block group is
The positioning protrusions are arranged in parallel, and a plurality of weight blocks are placed on the support body from the lower plane,
The stage block group excluding the first stage and the top stage is:
In the plurality of positioning lateral grooves, a positioning projection of each weight block one step below is fitted, and a plurality of weight blocks are stacked across each weight block below the one step,
The uppermost block group is:
A plurality of positioning lateral grooves are fitted with positioning projections of each weight block one step below the topmost stage, and one or a plurality of weight blocks are stacked across each weight block one step below the topmost stage. The weight block structure characterized by being made. The positioning protrusion is
Arranged in the center of the long block body in the width direction,
Each positioning lateral groove is
While being symmetrically arranged on both sides of the longitudinal center,
The weight block structure according to claim 1, wherein the weight block structures are arranged in parallel with a groove interval exceeding a block width between the left and right planes. Each weight block is
An opening is formed in the lower plane, and extends in the longitudinal direction of the long block body between the front and rear planes.
The weight block structure according to claim 1, further comprising a longitudinal groove that opens in the front-rear plane perpendicular to each positioning lateral groove. A weight block structure in which a plurality of weight blocks are stacked to form a multistage block group, and each stage block group is formed of one or more weight blocks,
Each weight block is
A long block body,
A positioning protrusion that is projected from the long block body and extends in the longitudinal direction of the long block body;
A plurality of openings are formed in the long block main body so as to face the positioning protrusions, and are arranged in parallel in the longitudinal direction at intervals, and penetrate the long block body in the width direction orthogonal to the longitudinal direction. Positioning lateral grooves;
Including
The first block group is
The positioning protrusions are arranged in parallel, and are configured by setting a plurality of weight blocks in parallel.
The stage block group excluding the first stage and the top stage is:
In the plurality of positioning lateral grooves, a positioning projection of each weight block one step below is fitted, and a plurality of weight blocks are stacked across each weight block below the one step,
The uppermost block group is:
A plurality of positioning lateral grooves are fitted with positioning projections of each weight block one step below the topmost stage, and one or a plurality of weight blocks are stacked across each weight block one step below the topmost stage. The weight block structure characterized by being made.

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