JP2014070391A - Demarcation fence - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress a curtain campus from fluttering nearby an end part owing to a wind even when water varies in level.SOLUTION: An upper edge part of a curtain campus 4 fitted with a sinker chain 3 is fitted to a lower edge side of an upper float part 2, and the curtain campus 4 is suspended in water. An end of a curtain campus upper edge part is connected to a wharf. The curtain campus 4 on a side linked to the connected end part is provided with tension chains 11, 12 along a campus longitudinal direction at a single region or a plurality of intermediate regions in a campus vertical direction. The tension chains 11, 12 are provided with intermediate float means 13, 14 of generating buoyant force canceling weights of the tension chains 11, 12 in a submerged state.

Description

  The present invention relates to a fraction fence that is provided in a dam lake, an artificial lake, or the like and separates water areas.

  For example, in a dam lake or the like, for the purpose of preventing pollution, a separation fence separating water areas is installed. Such a fraction fence is configured so that the curtain campus is suspended in water by attaching the upper edge of the curtain campus to which the weight means is attached to the lower edge side of the upper float portion, so that it does not move. Further, the end of the upper edge of the curtain campus is connected to a quay (see, for example, Patent Document 1).

JP 2004-261642 A

  Therefore, for example, when the water level decreases, as shown in FIG. 3, the portion of the fractionation fence 101 that is connected to the end of the curtain campus 102 connected to the quay S is exposed to the air according to the water level. It becomes the part 102b, 102d which floats on the water surface through the part which makes wall-shaped part 102a, 102c, and is in an unstable free state. As the wind blows, the unstable part of the curtain campus shakes. When the fluctuation becomes large, the portion connected to the end portion of the curtain campus is undulated so that the curtain campus may be damaged or broken.

  Therefore, an object of the present invention is to provide a fractionation fence that can suppress fluctuations caused by wind near the edge of the curtain campus even when the water level changes.

  The invention according to claim 1 is configured such that the curtain campus is suspended in water by attaching the upper edge of the curtain campus to which the weight means is attached to the lower edge side of the upper float portion. In the curtain campus on the side connected to the connected end portion, the edge of the edge is connected to the quay, and the longitudinal portion of the campus is located at one or more intermediate portions in the vertical direction of the campus. An intermediate weight means is provided along the direction, and an intermediate float means for generating a buoyancy force that counteracts the weight of the intermediate weight means in a submerged state with respect to the intermediate weight means is provided.

  In this way, since the intermediate weight means is provided in the vicinity of the curtain campus near the upper edge of the curtain campus, a part between the intermediate weight means and the upper edge of the curtain campus is located on the water surface. Even if it comes to be located above, the partial tension is increased by the downward load of the intermediate weight means, and the resistance force against the wind pressure of the wind is increased. Therefore, the fluctuation due to the wind can be suppressed near the end of the curtain campus.

  On the other hand, when the water level is high, the intermediate weight means sinks below the surface of the water, but an intermediate float means that generates buoyancy that counteracts the weight of the intermediate weight means is provided, so the weight of the intermediate weight means is intermediate. It is canceled out by the buoyancy of the float means, and the state is the same as when there is no intermediate weight means.

  According to a second aspect of the present invention, it is preferable that a reinforcing belt is provided along the longitudinal direction of the campus at the intermediate portion of the curtain campus where the intermediate weight means is provided.

  In this way, the intermediate weight means is provided in the portion (curtain campus) whose strength is increased by the reinforcing belt, which is advantageous in terms of durability.

  According to a third aspect of the present invention, the reinforcing belt may be configured such that the intermediate float means is provided in parallel with the intermediate weight means.

  In this way, it is possible to easily provide intermediate float means for generating buoyancy that counteracts the weight of the intermediate weight means in a submerged state.

  In the present invention, as described above, the intermediate weight means is provided in the portion near the upper edge of the curtain campus, so that a part between the intermediate weight means and the upper edge of the curtain campus is located on the water surface. Even if it becomes, the said part tension | tensile_strength increases and the resistance force with respect to the wind pressure of a wind can be raised. Therefore, even if the water level changes, fluctuations caused by wind can be suppressed near the end of the curtain campus, and the curtain campus can be prevented from being inadvertently damaged or broken.

A part of one Embodiment of the fractionation fence which concerns on this invention is shown, (a) is a front view, (b) is a top view. It is explanatory drawing of the connection part to a quay. It is explanatory drawing of the conventional fraction fence.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  1A and 1B show a part of an embodiment of a fractionation fence according to the present invention, in which FIG. 1A is a front view, FIG. 1B is a plan view, and FIG. 2 is an explanatory view of a connecting portion to a quay.

  The fraction fence 1 according to the present invention is arranged at an end, and as shown in FIGS. 1 (a) and 1 (b), below the upper float part 2 installed on the water, By attaching the upper part of the curtain campus 4 to which the weight chain 3 (weight) is attached, the curtain campus 4 is suspended in water. The fraction fence 1 is connected to an adjacent fraction fence (not shown) via a D-ring fitting 5 or the like, while the end D-ring fitting 5 is connected via a wire (not shown). It is connected to a quay (specifically, a concrete anchor block 21) (see FIG. 2) and separates a water area. The sink chain 3 is attached using, for example, an attachment belt. In FIG. 2, 22 is a wire rope and 23 is a shackle.

  The upper float part 2 has a cylindrical float covering cloth 5 (for example, made of PVC tarpaulin) and a plurality of floats 6 arranged at regular intervals therein. These floats 6 are covered with a float covering cloth 5 and are protected by the float covering cloth 5. Each float 6 is formed in a cylindrical body with a foamed resin (for example, made of polystyrene foam) having a small specific gravity, and has a diameter of 100 mm, for example.

  Wide first reinforcing belts 7A and 7B extending along the longitudinal direction of the campus are provided on the upper and lower sides of the curtain campus 4 at the upper and lower edges. A wide reinforcing belt (only the reinforcing belt 7C on the left edge is shown) extending along the vertical direction is provided. Similarly, narrow second reinforcing belts 8 </ b> A to 8 </ b> E extending along the longitudinal direction of the campus are also provided on the front and back sides of the intermediate portion in the vertical direction of the curtain campus 4. Further, narrow reinforcing belts 8F to 8H extending in the vertical direction of the campus are provided at regular intervals in the longitudinal direction of the campus. The reinforcing belts 7A to 7C and 8A to 8H are formed of, for example, a polyester woven cloth, and the width of the wide reinforcing belts 7A to 7C is about twice the width of the narrow reinforcing belts 8A to 8H. The reinforcement strength is higher than the central part of the campus.

  In addition, a tension chain for applying a downward load to the curtain campus 4 along the longitudinal direction of the campus at one or a plurality of intermediate portions in the vertical direction of the campus at a portion connected to the end of the campus connected to the quay. 11, 12 (intermediate weight means) are provided. A plurality of intermediate floats 13a, 14a (intermediate float means 13, 14) that generate buoyancy that counteracts the weight (downward load component) of the tension chains 11, 12 in a submerged state are provided for the tension chains 11, 12. Yes. Both the tension chain 11 and the intermediate float 12a are attached to portions where the reinforcing belts 8A and 8D are provided.

  Therefore, according to the fraction fence, when the water level is full, the tension chains 11 and 12 and the intermediate float means 13 and 14 are both submerged in water. It is canceled by the upward buoyancy caused by the intermediate float means 13 and 14, and is in the same state as when the tension chains 11 and 12 are not provided. Therefore, the original function as a fractionation fence is not impaired.

  On the other hand, when the water level falls, for example, the summer water limit level or the minimum water level, the curtain campus 4 on the water surface rises into a wall shape at the end connected to the quay and gradually approaches the center. The curtain campus 4 is folded and floated together with the float 6 on the water surface (see portions 102a to 102d in FIG. 3).

  In this state, when the wind blows, the portion of the curtain campus 4 that stands up in the shape of a wall sways under the wind pressure. Due to this fluctuation, the part lifts the float 6 and the curtain campus 4 floating on the center side, and when the fluctuation becomes large, the part connected to the end of the curtain campus is undulated so that the curtain The campus 4 may be damaged or broken.

  However, since the tension chains 11 and 12 are provided at the end of the curtain campus 4, the weight of the chain is prevented from shaking the curtain campus 4. That is, when the water level decreases and the tension chains 11 and 12 and the intermediate float means 13 and 14 are located in the air, the weight of the tension chains 11 and 12 is considerably larger than the weight of the intermediate float means 13 and 14. Therefore, the tension chains 11 and 12 function as weights with respect to the curtain campus 4, and the curtain campus 4 is pulled downward, thereby suppressing the swing of the curtain campus 4.

  Since tension chains 11 and 12 are provided at two intermediate positions in the vertical direction, each functions as a weight in the air, so that the load of the tension chains 11 and 12 can be efficiently applied to the curtain campus 4. Fluctuation can be suppressed.

  Therefore, since the swing can be suppressed, it is possible to prevent the curtain campus 4 from being damaged or broken due to the undulation so that the portion connected to the end portion of the curtain campus is violated.

  The present invention can be implemented by changing the embodiment as follows.

  (i) In the above embodiment, the intermediate float means 13 and 14 comprising a plurality of intermediate floats 13a and 14a are provided for the tension chains 11 and 12 (intermediate weight means), but the weight of the intermediate weight means is canceled out. If it is the float part which generate | occur | produces a buoyancy, it is also possible to make it one, and a shape in particular is not restrict | limited to a cylindrical body shape.

  (ii) In the above embodiment, a plurality of intermediate floats 13a, 14a (intermediate float means) that generate buoyancy that counteracts the weight of the intermediate weight means are attached to the tension chain 11, 12 (intermediate weight means) mounting portion (reinforcing belt). However, it is also possible to connect the intermediate float means to the attachment portion via intermediate connection means such as a wire rope.

  (iii) In the above embodiment, the intermediate weight means is a tension chain, but a plurality of weights provided at regular intervals may be used.

DESCRIPTION OF SYMBOLS 1 Fence 2 Upper float part 3 Weight sink chain 4 Curtain campus 5 Float covering cloth 6 Float 7A-7C, 8A-8H Reinforcement belt 11,12 Tension chain (intermediate weight means)
13, 14 Intermediate float means 13a, 14a Intermediate float

Claims (3)

By attaching the upper edge of the curtain campus to which the weight means is attached to the lower edge side of the upper float portion, the curtain campus is configured to be suspended in water, and the end of the upper edge of the curtain campus is A fractionation fence connected to the quay,
In the curtain campus on the side connected to the connected end, an intermediate weight means is provided along the longitudinal direction of the campus at one or more intermediate portions in the vertical direction of the campus,
A fractional fence comprising an intermediate float means for generating a buoyancy that counteracts the weight of the intermediate weight means in a submerged condition with respect to the intermediate weight means.
The fraction fence according to claim 1, wherein a reinforcing belt is provided along a longitudinal direction of the campus at a portion of the curtain campus where the intermediate weight means is provided.
  The fraction fence according to claim 2, wherein the intermediate float means is provided in parallel to the intermediate weight means on the reinforcing belt.

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