TWM606694U - Floating pipe interval control structure - Google Patents

Abstract

This creation is a floating tube spacing control structure, which is used to set on the floating tube in the first axis of a raft and located between two adjacent floating tubes in the second axis. The floating tube spacing control structure An abutting end is respectively formed at two opposite ends in the first axial direction, and the bottom of the floating tube spacing control structure forms a matching portion, the matching portion has a concave arc-shaped matching groove extending along the first axial direction, and The matching groove can match the tube wall of the floating tube in the first axis. The floating tube spacing control structure of the original creation can be tied to the floating tube in the first axis of the raft with an external tie rope, and the floating tube spacing control structure The two abutting ends respectively abut the two floating tubes in the second axis, thereby fixing the distance between the two floating tubes in the second axis, which can effectively prevent the floating tubes in the second axis from sliding due to wind and waves. In this case, the oyster seedling strings tied to the floating tube are prevented from getting knotted and affecting the operators to carry out the oyster harvesting operation.

Description

Floating pipe interval control structure

This creation is a floating tube spacing control structure, especially a floating tube spacing control structure that is set on a raft and used to control the spacing of the floating tubes of the raft.

Nowadays, when cultivating oyster seedlings, the string of oyster seedlings is mainly tied to a raft body, and the raft body is placed in a breeding pond. The raft body will float on the water surface, and the oyster seedling string will hang down. Into the water, wherein the raft includes a plurality of first axial floating tubes and a plurality of second axial floating tubes, the plurality of first axial floating tubes are arranged at intervals, and the plurality of second axial floating tubes The pipes are arranged at intervals and stacked with the plurality of floating tubes in the first axial direction. The intersecting positions of the plurality of floating tubes in the first axial direction and the plurality of floating tubes in the second axial direction are arranged by tying ropes or tubes. The kit is fixed, and the oyster seedling strings are respectively tied to the plurality of floating tubes.

However, since the surface of the floating tube is smooth, no matter whether it is tied by a rope or fixed by a tube set, the floating tube may be affected by wind and waves and cause relative sliding, so that oyster seedlings are tied. The distance between the floating pipes of the string is too short, which causes the oyster seedling string to be entangled and knotted, which causes inconvenience for the operators when collecting oysters. Therefore, how to effectively fix the floating pipes so that the adjacent floating pipes are not easily affected by wind and waves to produce relative sliding, which is actually the part of the current raft to be improved.

The main purpose of this creation is to provide a floating pipe spacing control structure, which hopes to improve the relative sliding of the floating pipes of the current raft body, which is susceptible to wind and waves, resulting in the entanglement and knotting of oyster seedlings, which in turn makes the operators There is a problem of inconvenience when picking oysters.

In order to achieve the purpose of the foregoing disclosure, the floating tube spacing control structure of this creation is used to set on the floating tube in the first axis of a raft and located between two adjacent floating tubes in the second axis. The two opposite ends of the floating tube spacing control structure in the first axial direction respectively form an abutting end, and the bottom of the floating tube spacing control structure forms a matching portion, the matching portion having a shape extending along the first axial direction A matching groove in the shape of a concave arc, and the matching groove can be matched with the tube wall of the floating tube in the first axial direction.

The top of the floating tube spacing control structure can further form an assembling part, and the assembling part has an assembling groove extending in the first axial direction in a concave arc shape; wherein the curvature radius of the assembling groove matches the The radii of curvature of the grooves are equal; or, the radius of curvature of the assembly groove can be greater than the radius of curvature of the matching groove.

Wherein, a through hole can be formed at the center of the floating tube interval control structure, and the floating tube interval control structure forms a peripheral wall on the periphery of the through hole; or, the floating tube interval control structure A plurality of through holes penetrating up and down can be formed in the center, and the plurality of through holes are arranged at intervals along the first axial direction of the floating tube spacing control structure, and the floating tube spacing control structure forms a peripheral wall, and the peripheral wall is Surround the plural through holes respectively.

In addition, two opposite sides of the peripheral wall are respectively recessed to form at least one side binding groove; and the peripheral wall can be further recessed to form at least one end binding groove respectively at the abutting ends of the floating tube interval control structure, and The floating tube spacing control structure respectively forms a through hole adjacent to the end binding groove.

The floating tube spacing control structure of the present invention can be tied to the floating tube in the first axial direction of the raft with an external tying rope, and the two abutting ends of the floating tube spacing control structure abut against the two respectively. The floating tube in the second axis can be used to fix the distance between the two floating tubes in the second axis. The floating tube in the second axis is affected by wind and waves and slips relative to the floating tube in the first axis, thereby avoiding the knotting of the oyster seedling strings tied to the floating tube and affecting the operation of the operator. Oyster operations.

10: butt end

11: Cooperating Department

111: Mating groove

12a, 12b: assembly department

121a, 121b: assembly groove

13: Through hole

14: Zhou wall

15: Side tie groove

16: End binding groove

17: Piercing hole

20: Side rope

21: End tie rope

30: Raft

31: Floating tube in the first axis

32: The second axial float tube

Figure 1: This is a three-dimensional schematic diagram of the first preferred embodiment of the created float tube interval control structure.

Figure 2: This is an end plan view of the first preferred embodiment of the created float tube spacing control structure.

Figure 3: This is a three-dimensional schematic diagram of the second preferred embodiment of the created float tube interval control structure.

Fig. 4 is a schematic diagram of the three-dimensional appearance of the third preferred embodiment of the created float tube interval control structure.

Figure 5: This is an end plan view of the third preferred embodiment of the created float tube spacing control structure.

Figure 6: This is a three-dimensional schematic diagram of the fourth preferred embodiment of the created float tube interval control structure.

Fig. 7 is a schematic diagram of the three-dimensional appearance of the fifth preferred embodiment of the created float tube interval control structure.

Figure 8: This is an end plan view of the fifth preferred embodiment of the created float tube spacing control structure.

Figure 9: This is a three-dimensional schematic diagram of the sixth preferred embodiment of the created float tube interval control structure.

Figure 10 is a schematic diagram of the use state of the fifth preferred embodiment of the created float tube interval control structure.

Figure 11: is a schematic cross-sectional view of Figure 10.

Figure 12: This is a schematic diagram of the use state of the sixth preferred embodiment of the created float tube interval control structure.

Please refer to Figures 1 to 10, which are several preferred embodiments of the floating tube spacing control structure created for this creation, which are used to be arranged on the floating tube 31 in the first axis of a raft 30 and located on the second axis Between the two adjacent floating tubes 32, the two opposite ends of the floating tube spacing control structure in the first axial direction respectively form an abutting end 10, and the bottom of the floating tube spacing control structure forms a matching The fitting portion 11 has a concave arc-shaped fitting groove 111 extending along the first axial direction, and the fitting groove 111 can fit the tube wall of the floating tube 31 in the first axial direction.

As shown in Figures 4-9, in the third preferred embodiment to the sixth preferred embodiment of the floating tube spacing control structure of the present creation, the top of the floating tube spacing control structure further forms an assembly portion 12a, 12b, the assembling parts 12a, 12b have a concave arc-shaped assembling groove 121a, 121b extending along the first axial direction; among them, the third preferred embodiment and the fourth type of the floating tube interval control structure are created in this invention In a preferred embodiment, the radius of curvature of the assembling groove 121a is equal to the radius of curvature of the mating groove 111; and the fifth and sixth preferred embodiments of the floating tube spacing control structure are created in this invention Wherein, the radius of curvature of the assembling groove 121b is greater than the radius of curvature of the matching groove 111, so that the floating tube spacing control structure can be used with floating tubes 31, 32 of different tube diameters.

In addition, as shown in Figures 1 and 4, in the first preferred embodiment and the third preferred embodiment of the floating tube spacing control structure of the present creation, the floating tube spacing control structure is formed with up and down in the center. A through hole 13 penetrates, and the floating pipe interval control structure forms a peripheral wall 14 on the periphery of the through hole 13.

As shown in Figure 3, Figure 6, Figure 7, Figure 9, and in the second preferred embodiment, the fourth preferred embodiment to the sixth preferred embodiment of the floating tube spacing control structure in this creation, The float pipe interval A plurality of through holes 13 that penetrate up and down is formed in the center of the control structure, and the plurality of through holes 13 are arranged at intervals along the first axial direction of the floating tube spacing control structure, and a peripheral wall 14 is formed on the floating tube spacing control structure, The peripheral wall 14 surrounds the plurality of through holes 13 respectively.

Furthermore, as shown in FIGS. 7-9, in the fifth preferred embodiment and the sixth preferred embodiment of the floating tube spacing control structure of the present invention, the two opposite sides of the peripheral wall 14 are respectively recessed to form at least One side binding groove 15; in addition, the peripheral wall 14 is respectively recessed at the abutting end 10 of the floating pipe spacing control structure to form at least one end binding groove 16, and the floating pipe spacing control structure is respectively adjacent to A through hole 17 is formed at the end binding groove 16.

Among them, the fifth preferred embodiment and the sixth preferred embodiment of the floating tube spacing control structure of the present creation as shown in Figures 7 and 9, the manufacturer can set the floating tube spacing control structure of different lengths. , In order to provide operators with suitable float tube spacing control structure according to the environment and use needs.

Among them, as shown in Fig. 10 and Fig. 12, the operator can choose to use multiple shorter-length floating tube spacing control structures in series with each other, or directly use a longer-length floating tube spacing control structure.

As shown in Figures 10 and 11, taking the fifth preferred embodiment of the floating tube spacing control structure of the present creation as an example, when the floating tube spacing control structure is in use, the operator can separate multiple floating tubes The control structures are connected in series, and the end tie ropes 21 are respectively passed through the end tie grooves 16 of the two adjacent float tube spacing control structures, and then pass through the through holes 17 to tie and fix them, and then connect to the work staff. The floating tube spacing control structure after the series connection can be placed on the floating tube 31 in the first axial direction of the raft body 30, so that the matching groove 111 of the floating tube spacing control structure after the series connection can match the first shaft The floating tube 31 is oriented toward the tube wall, and a plurality of side lashing ropes 20 respectively bypass the side lashing groove 15 of the floating tube spacing control structure, and tie the floating tube spacing control structure to the first On the axial floating tube 31, the abutting ends 10 of the opposite ends of the floating tube spacing control structure after the series connection can respectively abut against the two second axial floating tubes 32, thereby controlling the The distance between the two second-axis floating tubes 32 prevents the two second-axis floating tubes 32 from sliding relative to the first-axis floating tubes 31.

In addition, as shown in Figure 12, taking the sixth preferred embodiment of the floating tube spacing control structure of the present creation as an example, when the floating tube spacing control structure is in use, the operator directly sets the floating tube spacing control structure Is placed on the floating tube 31 in the first axial direction of the raft body 30 so that the matching groove 111 of the floating tube spacing control structure matches the tube wall of the floating tube 31 in the first axial direction, and has multiple sides The part tie ropes 20 respectively bypass the side tie grooves 15 of the floating tube spacing control structure, and tie the floating tube spacing control structure to the first axial floating tubes 31, 32 to make the floating tube The abutting ends 10 at the opposite ends of the pipe spacing control structure can respectively abut against the two second-axial floating pipes 32, thereby adjusting the distance between the two second-axial floating pipes 32, so that the second The two-axis floating tube 32 will not slip relative to the first-axis floating tube 31.

In addition, the floating tube spacing control structure can use its own length to provide the spacing control between the two second axial float tubes 32. When the operator sets the floating tube spacing control structure, the floating tube spacing The abutting end 10 of the control structure can directly abut the two second-axial floating tubes 32 to directly provide the spacing control of the two second-axial floating tubes 32; or, the floating tube spacing control structure The abutting ends can respectively maintain a gap with the two second-axial floating tubes 32. When wind and waves cause the two second-axial floating tubes 32 to slide, the floating tube spacing control structure can enable the two floating tubes 32 to slide. The floating tube 32 in the second axis still maintains a certain interval distance, thereby achieving the effect of interval control.

Furthermore, when the raft includes a plurality of transverse floating tubes and a plurality of longitudinal floating tubes arranged in different axial directions, the transverse floating tubes can be used as the aforementioned first axial floating tubes 31, and the longitudinal floating tubes can be As the aforementioned second axial floating tube 32, the transverse floating tube can provide the floating tube spacing control structure setting, and the floating tube spacing control structure provides spacing control between the longitudinal floating tubes; or Yes, the longitudinal floating tube can be used as the aforementioned first axial floating tube 31, and the horizontal floating tube can be used as the aforementioned second axial floating tube 32, and the longitudinal floating tube can provide the floating tube An interval control structure is provided, and the float tube interval control structure provides interval control between the transverse float tubes.

In summary, the floating tube spacing control structure of the present creation can be tied to the floating tube 31 in the first axial direction of the raft 30 by using an external lashing rope, and the two floating tube spacing control structures can abut The terminals 10 respectively abut against the two second-axis floating tubes 32, thereby fixing the distance between the two second-axis floating tubes 32, which can effectively avoid the second-axis floating tubes 32 of the raft 30 Under the influence of wind and waves, there is a slippage relative to the floating tube 31 in the first axis, thereby preventing the oyster seedling strings tied to the floating tubes 31 and 32 from knotting each other and affecting the operator to carry out oyster harvesting operations.

10: butt end

12b: Assembly Department

121b: assembly slot

14: Zhou wall

15: Side tie groove

16: End binding groove

17: Piercing hole

20: Side rope

21: End tie rope

30: Raft

31: Floating tube in the first axis

32: The second axial float tube

Claims (12)

A floating tube spacing control structure, which is used to be arranged on a floating tube in a first axis of a raft and located between two adjacent floating tubes in a second axis. The floating tube spacing control structure is The two opposite ends of the first axial direction respectively form an abutting end, and the bottom of the floating tube spacing control structure forms a matching part, and the matching part has a concave arc-shaped matching part extending along the first axial direction A groove, and the matching groove can fit the tube wall of the floating tube in the first axial direction. The floating tube spacing control structure according to claim 1, wherein the top of the floating tube spacing control structure forms an assembling part, and the assembling part has a concave arc-shaped assembling groove extending along the first axial direction. The floating pipe spacing control structure according to claim 2, wherein the radius of curvature of the fitting groove is equal to the radius of curvature of the matching groove. The floating pipe spacing control structure according to claim 2, wherein the radius of curvature of the assembly groove is greater than the radius of curvature of the mating groove. The floating pipe interval control structure according to any one of claims 1 to 4, wherein a through hole is formed in the center of the floating pipe interval control structure, and the floating pipe interval control structure is formed in the through hole. The periphery of the hole forms a perimeter wall. The floating tube spacing control structure according to any one of claims 1 to 4, wherein a plurality of through holes penetrating up and down is formed in the center of the floating tube spacing control structure, and the plurality of through holes is controlled along the floating tube spacing The structures are arranged at intervals in the first axial direction, and a peripheral wall is formed on the floating tube spacing control structure, and the peripheral wall respectively surrounds the plurality of through holes. The floating pipe spacing control structure according to claim 5, wherein two opposite sides of the peripheral wall are respectively recessed to form at least one side binding groove. The floating pipe spacing control structure according to claim 6, wherein two opposite sides of the peripheral wall are respectively recessed to form at least one side binding groove. The floating tube spacing control structure according to claim 5, wherein the peripheral walls are respectively recessed at the abutting ends of the floating tube spacing control structure to form at least one end binding grooves, and the floating tube spacing control structures are respectively A through hole is formed adjacent to the end binding groove. The floating tube spacing control structure according to claim 6, wherein the peripheral walls are respectively recessed at the abutting ends of the floating tube spacing control structure to form at least one end binding grooves, and the floating tube spacing control structures are respectively A through hole is formed adjacent to the end binding groove. The floating tube spacing control structure according to claim 7, wherein the peripheral walls are respectively recessed at the abutting ends of the floating tube spacing control structure to form at least one end binding grooves, and the floating tube spacing control structures are respectively A through hole is formed adjacent to the end binding groove. The floating tube spacing control structure according to claim 8, wherein the peripheral walls are respectively recessed at the abutting ends of the floating tube spacing control structure to form at least one end binding grooves, and the floating tube spacing control structures are respectively A through hole is formed adjacent to the end binding groove.

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