JP5809069B2 - Spar type floating structure - Google Patents

Description

  The present invention relates to a spar type floating structure that is suspended on the ocean or the like, and more particularly, to a spar type floating structure that can suppress fluctuations caused by external forces such as waves and winds.

  In recent years, offshore wind power generation has attracted attention from the viewpoint of the preservation of the global environment and the effective use of natural energy. As a floating structure for offshore wind power generation, a spar type (cylindrical buoy type) that ensures static stability with the center of gravity always below the buoyancy, and a TLP (Tension Leg Platform) that tensions the floating body with tension legs Various types have been proposed such as a barge type (barge type) that achieves stability by a mold and a contact surface with water.

  Among these floating structures, the spar type is considered to be advantageous over other floating structures in terms of cost. On the other hand, a spar-type floating structure is a structure that holds floating structures floating on the water with ropes, so that the swinging such as yawing, pitching, and rolling is rolling. Some methods for suppressing these fluctuations have already been proposed (see, for example, Patent Document 1 and Patent Document 2).

  For example, Patent Document 1 includes a structure having buoyancy, a movable plate that receives a wave force, and a coupler that connects a side of the structure and the movable plate, and a coupling portion of the coupler. Includes a spring and an attenuator that includes a spring and an attenuator for controlling the rotational shaking of the movable plate so as to cancel the horizontal shaking of the structure caused by wave force. A prevention device is disclosed.

  Further, Patent Document 2 discloses a floating-type foundation structure for standingly supporting a generator system on the ocean. The foundation structure includes a central structure for standingly supporting the generator system, and a generator. A main floating body in which the lower part of the central structure in a state where the system is erected and supported is placed underwater, and a variable buoyancy caused by waves is accommodated, and the central structure is installed in the central structure to maintain a vertical restoring force. A floating foundation structure for offshore wind power generation, which includes a tower floating body portion and a mooring device for mooring the foundation structure, is disclosed. Here, the main floating body is formed, for example, in a flat plate shape so as to reduce the lateral force such as the shaking especially by the wave forcing force, and in order to reduce the external force against the incident wave from all directions. It arrange | positions radially via a strength member with respect to a structure.

JP 59-227589 A JP 2002-285951 A

  However, in the vibration reduction method described in Patent Document 1 described above, since the movable plate and the structure are mechanically coupled by the coupler, a large load is applied to the coupler by an external force such as a wave, and a failure occurs. There was a problem that it was easy to do. Moreover, in the fluctuation reduction method described in Patent Document 2, there is a problem that the structure is complicated and the cost merit of the spar type floating structure is lost. In addition, a method of reducing the fluctuation by increasing the number of cords used conventionally can be considered, but there are problems such as an increase in cost and difficulty in maintenance.

  The present invention has been devised in view of the above-described problems, and an object of the present invention is to provide a spar-type floating structure that can suppress fluctuations caused by external forces such as waves and winds at low cost.

According to the present invention, in a spar type floating body structure having a floating body portion having a columnar shape and an upper structure disposed above the floating body portion, an annular member inserted through the outer periphery of the floating body portion; It possesses a first rope connecting the annular member and the floating body, and a second cord for connecting the annular member and the sea bed, a said annular member is disposed about the force applied point of the floating body There is provided a spar type floating structure characterized by being a cylindrical floating body . Here, the upper structure is, for example, a wind power generator.

Before SL annular member may be more than one in the radial direction or the axial direction of the floating body.

  The first rope may be connected to the floating body portion at a position above the annular member, or may be connected to the floating body portion at a position below the annular member. You may be connected to the said floating-body part in both the upper and lower positions rather than a member. Moreover, the number of said 1st rope is more than the number of said 2nd rope, for example.

  The spar type floating structure may include a second annular member inserted through the outer periphery of the annular member, and a third rope connecting the second annular member and the annular member.

  According to the spar type floating body structure of the present invention described above, by arranging the annular member between the floating body portion and the rope, the tension acting on the floating body portion can be easily increased, and waves, winds, etc. The fluctuation of the floating body part due to external force can be suppressed. In addition, since the annular member can float independently of the floating body portion, if the floating body portion tries to move the annular member, the water pressure acting on the annular member becomes resistance and suppresses the swinging of the floating body portion. it can.

  Further, since the annular member is only connected to the floating body portion by the first rope, it can be easily manufactured at a low cost and hardly causes a failure. Furthermore, since the annular member and the first rope are disposed closer to the water surface than the second rope extended to the bottom of the water, maintenance can be easily performed.

It is a whole lineblock diagram showing the spar type floating body structure concerning a first embodiment of the present invention. It is a figure for demonstrating the effect | action of the spar type | mold floating body structure shown in FIG. 1, (a) shows a partial side view, (b) shows the BB cross-sectional arrow view in FIG. 2 (a). Yes. It is a partial side view for demonstrating the effect | action of the spar type | mold floating body structure shown in FIG. 1, (a) at the time of floating body part tilting, (b) at the time of floating body part raising, (c) at the time of floating body part lowering, Is shown. It is a horizontal section arrow view which shows the spar type | mold floating body structure which concerns on other embodiment of this invention, (a) is 2nd embodiment, (b) is 3rd embodiment, (c) is 4th embodiment. , (D) shows the fifth embodiment. It is a figure which shows the spar type | mold floating body structure which concerns on 6th embodiment of this invention, (a) is a partial side view, (b) has shown the BB cross-sectional arrow view in Fig.5 (a). . It is a partial side view which shows the spar type | mold floating body structure which concerns on other embodiment of this invention, (a) shows 7th embodiment, (b) shows 8th embodiment, (c) shows 9th embodiment. ing.

  Hereinafter, embodiments of the present invention will be described with reference to FIGS. Here, FIG. 1 is an overall configuration diagram showing a spar type floating body structure according to the first embodiment of the present invention. 2A and 2B are views for explaining the operation of the spar type floating structure shown in FIG. 1, wherein FIG. 2A is a partial side view, and FIG. 2B is a cross-sectional view taken along line BB in FIG. , Shows. 3 is a partial side view for explaining the operation of the spar type floating structure shown in FIG. 1. (a) is when the floating body is tilted, (b) is when the floating body is raised, and (c) is the floating body. When the unit is descending.

  As shown in FIG. 1, the spar type floating body structure 1 according to the first embodiment of the present invention includes a floating body portion 2 having a columnar shape and an upper structure 3 disposed on the upper portion of the floating body portion 2. The annular member 4 inserted through the outer periphery of the floating body 2, the first rope 5 connecting the annular member 4 and the floating body 2, and the second rope 6 connecting the annular member 4 and the bottom G Have.

  The spar type floating body structure 1 is, for example, a floating body structure for an offshore wind power generator disposed on a relatively deep ocean, and a wind power generator is disposed as the upper structure 3. Such a wind turbine generator includes, for example, a support 31, a nacelle 32, and a blade 33. The column 31 is erected on the top of the floating body 2 and supports the nacelle 32 and the blade 33. The nacelle 32 has a generator inside, and generates electric power by the rotation of the blade 33. The blade 33 is rotationally driven by wind power. Such a wind power generator is an example of the upper structure 3 installed in the spar type floating structure 1, and wind conditions such as an anemometer and an anemometer are used together with or instead of the wind power generator. An observation device, a solar power generation device, a lighting device, a wireless communication device, or the like may be installed.

  The floating body 2 has a substantially cylindrical shape and constitutes a column portion that gives buoyancy to the upper structure 3. The inside of the floating body portion 2 is formed in a cavity, and generates buoyancy enough to float while standing in water with the upper structure 3 installed. In addition, a fixed amount of ballast having a constant weight may be disposed inside the floating body 2, or a ballast tank capable of adjusting the amount of ballast by pouring and draining seawater may be disposed. Moreover, in order to reduce resistance due to water flow or waves, the floating body 2 may have a shape that is partially widened in water, or may have a shape that is widened at a portion including the water line. .

  The annular member 4 is a cylindrical floating body that is arranged around the force applied point of the floating body portion 2. Here, the applied force point means an action point when the force acting on the structure is expressed as a single point. In the case of the spar type floating structure 1, the water pressure acting on the floating body portion 2 is expressed. It will point to the center. For example, in the illustrated embodiment, the applied force point is located at the intersection of the horizontal central section H of the annular member 4 and the axis L of the spar type floating structure 1.

  Further, as illustrated, the annular member 4 is disposed so as to have a certain gap from the outer peripheral surface of the floating body 2 (see FIG. 2B). At this time, the inner surface of the annular member 4 is formed so as to correspond to the shape of the outer peripheral surface of the floating body 2. For example, when the outer peripheral surface of the floating body 2 has a circular cross section, the inner surface of the annular member 4 is also formed in a circular cross section, and when the outer peripheral surface of the floating body 2 has a polygonal cross section, the inner surface of the annular member 4 is also the same. Formed in a polygonal cross section. Conditions such as the volume of the annular member 4, the height of the annular member 4, and the surface area of the upper surface or the lower surface are appropriately set depending on conditions such as wind force and water flow where the spar-type floating structure 1 is disposed. The vertical cross-sectional shape of the annular member 4 may be a rectangle, a circle or an ellipse, or another polygon or a curved surface.

  The first rope 5 is a component that connects the annular member 4 and the floating body 2. The first rope 5 can be made of the same material as that of a rope mooring a normal floating body. For example, the first rope 5 is made of a chain or rope having a strength capable of holding a heavy object. In addition, the first rope 5 includes, for example, an upper first rope 51 connected to the upper part of the annular member 4 and the annular member when the annular member 4 is a neutral buoyancy type (a balance between weight and buoyancy). 4 and a lower first rope 52 connected to the lower portion of the first wire. That is, the first rope 5 is connected to the floating body 2 at both positions above and below the annular member 4.

  Specifically, as shown in FIGS. 1 and 2 (b), the upper first rope 51 has connection points P1, P3, P5, P7 connected to the outer peripheral surface of the floating body 2, for example. The connection points P2, P4, P6, and P8 connected to the upper surface of the annular member 4 are provided. Here, the connection points P2, P4, P6, and P8 may be disposed on the inner edge side of the annular member 4, may be disposed on the center portion of the upper surface, or may be disposed on the outer edge side. Good. Then, by the upper first rope 51, the connection point P1 and the connection point P2, the connection point P2 and the connection point P3, the connection point P3 and the connection point P4, the connection point P4 and the connection point P5, the connection point P5 and the connection point P6, and the connection The point P6 is connected to the connection point P7, the connection point P7 is connected to the connection point P8, and the connection point P8 is connected to the connection point P1.

  Similarly, the lower first rope 52 causes the connection point P1 ′ and the connection point P2 ′, the connection point P2 ′ and the connection point P3 ′, the connection point P3 ′ and the connection point P4 ′, and the connection point P4 ′ and the connection point. P5 ′, connection point P5 ′ and connection point P6 ′, connection point P6 ′ and connection point P7 ′, connection point P7 ′ and connection point P8 ′, and connection point P8 ′ and connection point P1 ′ are connected to each other.

  The second cord 6 is a component that connects the annular member 4 and the water bottom G. The second rope 6 is substantially the same component as a rope mooring a conventional floating body, and is fixed to the water bottom G by an anchor 61. For example, three or more second cords 6 are arranged, preferably about three to four. By the way, the number of the first ropes 5 is preferably equal to or greater than the number of the second ropes 6. By partially increasing the number of cords connected to the floating body 2, the tension acting on the floating body 2 can be easily increased. In the present embodiment, a total of 16 first ropes 5, 8 as the upper first ropes 51 and 8 as the lower first ropes 52, are connected to the floating body 2 via the annular member 4, and the second ropes The number is set to 6 or more. In addition, the number of the 1st rope 5 and the 2nd rope 6 is not limited to what was illustrated.

  Here, the effect | action of the spar type | mold floating body structure 1 mentioned above is demonstrated, referring FIG.2 and FIG.3. FIG. 2 shows a case where a yaw is generated in the spar type floating structure 1, and FIG. 3A shows a case where a pitching or a side roll (rolling) occurs in the spar type floating structure 1. 3 (b) and 3 (c) show the case where the spar type floating body structure 1 is vertically shaken (heaving). In addition, the figure of the 2nd rope 6 is abbreviate | omitted in each figure of FIG.

  First, a case where a sway (yaw) occurs in the spar type floating structure 1 will be described. When yaw is generated in the spar type floating body structure 1, the floating body portion 2 rotates around the axis L. For example, as shown in FIGS. 2A and 2B, when the floating body 2 tries to rotate clockwise (clockwise), the floating body 2 tends to rotate relative to the annular member 4. Connection point P1 (P1 ') and connection point P2 (P2'), connection point P3 (P3 ') and connection point P4 (P4'), connection point P5 (P5 ') and connection point P6 (P6'), connection The first rope 5 (upper first rope 51 and lower first rope 52) connecting the point P7 (P7 ') and the connection point P8 (P8') has tension (reverse force) as shown by arrows in the figure. Force) is generated and tries to prevent rotation of the floating body 2. Therefore, rotation around the axis L of the floating body portion 2 is suppressed, and yaw of the spar type floating body structure 1 is reduced.

  Next, a case where pitching or rolling (rolling) occurs in the spar type floating structure 1 will be described. When yawing (sway) occurs in the spar type floating body structure 1, the axis L of the floating body 2 is tilted in one direction. For example, as shown in FIG. 3A, when the floating body 2 is inclined to the right, the floating body 2 tends to move relative to the annular member 4, and therefore, the connection point P3 and the connection point P2, The upper first rope 51 that connects the connection point P5 and the connection point P4, the connection point P7 and the connection point 6, the connection point P1 and the connection point P8, and the connection point P1 ′ and the connection point P2 ′ and the connection point P3 ′ The lower first rope 52 connecting the connection point P4 ′, the connection point P5 ′ and the connection point P6 ′, and the connection point P7 ′ and the connection point P8 ′ has tension (reaction force) as shown by the arrows in the figure. Occurs and tries to prevent tilting of the floating body 2. Therefore, the tilt of the axis L of the floating body portion 2 is suppressed, and pitching and rolling (rolling) of the spar type floating structure 1 are reduced.

  Next, a case where vertical swing (heaving) occurs in the spar type floating structure 1 will be described. First, as shown in FIG. 3B, a case where the spar type floating structure 1 is raised will be considered. At this time, since the floating body portion 2 tends to move upward relative to the annular member 4, the upper first rope 51 is tensioned and the lower first rope 52 is relaxed. The upper first rope 51 connecting the connection point P1 and the connection points P2 and P8, the connection point P3 and the connection points P2 and P4, the connection point P5 and the connection points 4 and P6, and the connection point P7 and the connection points P6 and P8. As shown by the arrows in the figure, tension (reaction force) is generated and tries to prevent the floating body 2 from rising.

  Then, as shown in FIG.3 (c), consider the case where the spar type | mold floating body structure 1 descend | falls. At this time, since the floating body portion 2 tends to move downward relative to the annular member 4, the lower first rope 52 is tensioned and the upper first rope 51 is relaxed. Then, the connection point P1 ′ and the connection points P2 ′ and P8 ′, the connection point P3 ′ and the connection points P2 ′ and P4 ′, the connection point P5 ′ and the connection points 4 ′ and P6 ′, the connection point P7 ′ and the connection point P6 ′. , P8 ′, a tension (reaction force) is generated on the lower first rope 52 connecting the lower first ropes 52 as shown by the arrows in the drawing, so that the lowering of the floating body 2 is prevented.

  Therefore, the first rope 5 (the upper first rope 51 and the lower first rope 52) suppresses the rising and lowering of the floating body portion 2, and the vertical swing (heaving) of the spar type floating structure 1 is reduced.

  As described above, according to the spar-type floating structure 1 of the present invention described above, the number of ropes connected to the floating body 2 can be easily increased by disposing the annular member 4 between the floating body 2 and the rope. Therefore, the tension acting on the floating body 2 can be easily increased, and the floating of the floating body 2 can be suppressed. In addition, since the annular member 4 can float independently of the floating body portion 2, if the floating body portion 2 tries to move the annular member 4, the water pressure acting on the annular member 4 becomes resistance, and the floating body portion 2 Swaying can be suppressed.

  Further, since the annular member 4 is only connected to the floating body 2 by the first rope 5, it can be easily manufactured at a low cost and is unlikely to cause a failure. Furthermore, since the annular member 4 and the first rope 5 are disposed closer to the water surface than the second rope 6 extended to the bottom of the water, maintenance can be easily performed.

  Next, a spar type floating structure 1 according to another embodiment of the present invention will be described with reference to FIGS. Here, FIG. 4 is a horizontal sectional view showing a spar type floating structure according to another embodiment of the present invention, (a) is the second embodiment, (b) is the third embodiment, ( c) shows a fourth embodiment, and (d) shows a fifth embodiment. FIG. 5 is a view showing a spar type floating body structure according to a sixth embodiment of the present invention, in which (a) is a partial side view, and (b) is a cross-sectional view taken along line BB in FIG. Is shown. FIG. 6 is a partial side view showing a spar type floating structure according to another embodiment of the present invention, in which (a) is the seventh embodiment, (b) is the eighth embodiment, and (c) the ninth embodiment. Form. In addition, in each figure, about the same component as 1st embodiment mentioned above, the same code | symbol is attached | subjected and the overlapping description is abbreviate | omitted.

  In the second embodiment shown in FIG. 4A, the number of first ropes 5 is smaller than that in the first embodiment. Specifically, the upper first rope 51 includes connection points P1, P4, P7 connected to the floating body 2, connection points P2, P3, P5, P6, P8, P9 connected to the annular member 4, Have

  That is, the upper first rope 51 includes the connection point P1 and the connection point P2, the connection point P3 and the connection point P4, the connection point P4 and the connection point P5, the connection point P6 and the connection point P7, the connection point P7 and the connection point P8, and the connection. It is composed of six ropes connecting the point P9 and the connection point P1. Here, the connection points P2 and P3, the connection points P5 and P6, and the connection points P8 and P9 on the annular member 4 may be configured by the same connection point, or two connection points P1, P4, and P7 may be formed. You may make it isolate | separate into a point. Although not shown, the lower first rope 52 also has the same configuration as the upper first rope 51, and twelve first ropes 5 are arranged in the floating body 2 as a whole.

  In the third embodiment shown in FIG. 4B, the number of the first ropes 5 is larger than that in the first embodiment. Specifically, the upper first rope 51 has connection points P1, P3, P5, P7, P9 connected to the floating body 2 and connection points P2, P4, P6, P8, P10 connected to the annular member 4. And having.

  That is, the upper first rope 51 includes the connection point P1 and the connection point P2, the connection point P2 and the connection point P3, the connection point P3 and the connection point P4, the connection point P4 and the connection point P5, the connection point P5 and the connection point P6, and the connection. Consists of ten lines connecting the point P6 and the connection point P7, the connection point P7 and the connection point P8, the connection point P8 and the connection point P9, the connection point P9 and the connection point P10, and the connection point P10 and the connection point P1. . Each of the connection points P1 to P10 may be separated into two points. Although not shown, the lower first rope 52 has the same configuration as the upper first rope 51, and 20 first ropes 5 are disposed in the floating body 2 as a whole. .

  In the fourth embodiment shown in FIG. 4C, the number of the first ropes 5 is larger than that in the third embodiment. Specifically, the upper first rope 51 has connection points P1 to P23 (odd jumps) connected to the floating body 2 and connection points P2 to P24 (even jumps) connected to the annular member 4.

  That is, the upper first rope 51 has 24 wires connecting the connection point P1 and the connection point P2, the connection point P2 and the connection point P3,..., The connection point P23 and the connection point P24, and the connection point P24 and the connection point P1. It is made up of Each connection point P1 to P24 may be separated into two points. Although not shown, the lower first rope 52 has the same configuration as the upper first rope 51, and 48 first ropes 5 are arranged in the floating body 2 as a whole.

  In the fifth embodiment shown in FIG. 4D, the first rope 5 is arranged without being inclined in the circumferential direction. In the first rope 5 shown in the first embodiment to the fourth embodiment described above, in order to improve the responsiveness, the first rope 5 is arranged so as to be inclined in the circumferential direction between the floating body portion 2 and the annular member 4. However, the first rope 5 may be arranged in a substantially vertical direction as shown in a place where the fluctuation is not large. Specifically, the upper first rope 51 has connection points P1, P3, P5, P7, P9, P11 connected to the floating body 2 and connection points P2, P4, P6, P8 connected to the annular member 4. , P10, P12.

  That is, the upper first rope 51 includes the connection point P1 and the connection point P2, the connection point P3 and the connection point P4, the connection point P5 and the connection point P6, the connection point P7 and the connection point P8, the connection point P9 and the connection point P10, and the connection. It consists of six ropes connecting the point P11 and the connection point P12. Although not shown, the lower first rope 52 also has the same configuration as the upper first rope 51, and twelve first ropes 5 are arranged in the floating body 2 as a whole.

  In the sixth embodiment shown in FIGS. 5A and 5B, the second annular member 7 inserted through the outer periphery of the annular member 4 and the third rope connecting the second annular member 7 and the annular member 4 are used. 8. Since the structure of the annular member 4 and the first rope 5 is the same as that of the first embodiment described above, detailed description thereof is omitted here.

  Similar to the annular member 4, the second annular member 7 is a cylindrical floating body that is disposed around the force application point of the floating body portion 2. Further, as shown in FIG. 5B, the second annular member 7 is disposed so as to have a certain gap from the outer peripheral surface of the annular member 4. At this time, the inner surface of the second annular member 7 is formed so as to correspond to the shape of the outer peripheral surface of the annular member 4. Conditions such as the volume of the second annular member 7, the height of the second annular member 7, and the surface area of the upper surface or the lower surface are appropriately set according to conditions such as wind force and water flow where the spar type floating structure 1 is disposed. . The vertical cross-sectional shape of the second annular member 7 may be a rectangle, a circle or an ellipse, or another polygon or a curved surface.

  The third cord 8 is a component that connects the annular member 4 and the second annular member 7. The third cord 8 is made of the same material as the first cord 5 described above, for example. Further, the third cord 8 is disposed in the horizontal center section H as shown in FIG. 5A, for example, and is connected to the outer peripheral surface of the annular member 4 as shown in FIG. 5B. Connection points P101, P103, P105, P107, and P109, and connection points P102, P104, P106, P108, and P110 connected to the inner peripheral surface of the second annular member 7.

  That is, the third cord 8 includes the connection point P101 and the connection point 102, the connection point P102 and the connection point 103, the connection point P103 and the connection point 104, the connection point P104 and the connection point 105, the connection point P105 and the connection point 106, and the connection point. P106 and connection point 107, connection point P107 and connection point 108, connection point P108 and connection point 109, connection point P109 and connection point 110, and connection point P110 and connection point 101 are constituted by ten cables. Each connection point P101 to P110 may be separated into two points. Further, when the annular member 4 and the second annular member 7 are sufficiently high, the third cord 8 is separated into the upper third cord and the lower third cord like the first cord 5. May be.

  In the illustrated embodiment, the connection points of the first rope 5 (for example, the upper first rope 51) to the floating body portion 2 are four points, and the connection points of the third rope 8 to the annular member 4 are five points. However, the number of points is not limited to this, and the number of connection points of the first cable 5 and the number of connection points of the third cable 8 may be the same, or may be configured to be a combination of other points. May be.

  According to the structure which concerns on 6th embodiment mentioned above, the number of the ropes which restrain floating body part 2 is arranged by arranging a plurality of annular members (annular member 4 and second annular member 7) in the diameter direction of floating body part 2. Further, the reaction force (tension) with respect to the relative rotation and relative movement of the floating body 2 can be easily increased, and the spar-type floating structure 1 can be prevented from shaking. The number of annular members arranged in the radial direction is not limited to two, and may be three or more.

  In the seventh embodiment shown in FIG. 6A, the lower first rope 52 is omitted from the first rope 5, and the annular member 4 is suspended by the upper first rope 51. Therefore, it can be said that the first rope 5 is connected to the floating body 2 at a position above the annular member 4. Such a configuration is suitable when the weight of the annular member 4 is larger than the buoyancy. That is, when the annular member 4 has a relationship of weight> buoyancy, the annular member 4 is subjected to a force to sink downward due to gravity, so even if the lower first rope 52 is omitted, the annular member 4 The position can be stabilized. In addition, the figure of the 2nd rope 6 is abbreviate | omitted in this figure.

  In the eighth embodiment shown in FIG. 6B, the upper first rope 51 is omitted from the first rope 5, and the annular member 4 is supported by the lower first rope 52. Therefore, it can be said that the first rope 5 is connected to the floating body 2 at a position below the annular member 4. Such a configuration is suitable when the buoyancy of the annular member 4 is greater than the weight. That is, when the annular member 4 has a relationship of weight <buoyancy, the annular member 4 is subjected to a force to lift upward due to the buoyancy, so even if the upper first rope 51 is omitted, the annular member 4 is omitted. The position of can be stabilized. In addition, the figure of the 2nd rope 6 is abbreviate | omitted in this figure.

  In the ninth embodiment shown in FIG. 6C, a plurality of annular members 4 are arranged in the axial direction of the floating body portion 2. For example, in the case of the floating body 2 having a deep draft, a plurality of annular members 4 can be arranged in parallel in the axial direction of the floating body 2. Also with this configuration, the number of ropes connected to the floating body 2 can be easily increased, and the reaction force (tension) against the relative rotation and relative movement of the floating body 2 can be easily increased. The shaking of the object 1 can be suppressed. Although not shown, the second cord 6 may be connected to each annular member 4 with its tip branched, or may be connected to each annular member 4.

  The present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the spirit of the present invention, for example, the first embodiment to the ninth embodiment may be appropriately combined. Of course there is.

DESCRIPTION OF SYMBOLS 1 Spar type | mold floating body structure 2 Floating body part 3 Upper structure 4 Annular member 5 First rope 6 Second rope 7 Second annular member 8 Third rope

Claims (6)

In a spar type floating body structure having a floating body portion having a columnar shape, and an upper structure disposed on top of the floating body portion,
An annular member inserted through the outer periphery of the floating body;
A first rope connecting the annular member and the floating body part;
Have a, a second cord that connects the annular member and the bottom of the water,
The annular member is a cylindrical floating body that is arranged around the point of application of the floating body.
A spar-type floating structure characterized by that.   The first rope is connected to the floating body portion at a position above the annular member, connected to the floating body portion at a position below the annular member, or above the annular member. 2. The spar type floating structure according to claim 1, wherein the spar type floating structure is connected to the floating body at both of the positions below and below.   2. The spar-type floating structure according to claim 1, wherein the number of the first ropes is equal to or greater than the number of the second ropes.   The spar type floating body structure according to claim 1, wherein a plurality of the annular members are arranged in a radial direction or an axial direction of the floating body portion.   2. The spar type floating structure according to claim 1, comprising: a second annular member inserted through an outer periphery of the annular member; and a third rope connecting the second annular member and the annular member. object.   The spar type floating structure according to claim 1, wherein the upper structure is a wind power generator.