Abstract
The present invention discloses a bionic high holding power anchor, which includes an anchor rod, a suspension clasp coupled with one end of the anchor rod and an anchor fluke hinged with the other end of the anchor rod, wherein a plurality of fluke heads arranged at equal intervals are extended from a front end of the anchor fluke, fin-like streamlined balance wings are arranged at two sides of the anchor fluke; the fluke head is in a shape of triangle-like taper containing a plane side wall and two curved side walls, the plane side wall is an isosceles triangle, the two curved side walls are smooth curved surfaces, and the two smooth curved surfaces are symmetrical around a normal plane of the plane side wall. According to the bionic high holding power anchor of the present invention, the balance wings are arranged at the two sides of the anchor fluke, a body is avoided from being turned completely and the anchor reaches to a soil layer at a correct working angle during a process that the anchor is thrown into water; and a longitudinal dimension of the anchor is increased, so that an anti-turning property of the anchor in the soil layer is improved significantly, and a risk of anchor dragging is reduced.
Claims
1. A bionic high holding power anchor, comprising an anchor rod, a suspension clasp coupled with one end of the anchor rod and an anchor fluke hinged with the other end of the anchor rod, wherein a plurality of fluke heads arranged at equal intervals are extended from a front end of the anchor fluke, fin-like streamlined balance wings are arranged at two sides of the anchor fluke; the fluke head is in a shape of triangle-like taper containing a plane side wall and two curved side walls, the plane side wall is an isosceles triangle, the two curved side walls are smooth curved surfaces, and the two smooth curved surfaces are symmetrical around a normal plane of the plane side wall.
2. The bionic high holding power anchor according to claim 1, wherein the fluke head comprises a first half-fluke and a second half-fluke, the first half-fluke and the second half-fluke are symmetric around the plane side wall, a soil-penetrating angle of the first half-fluke θ is greater than 22° but less than 40°, a soil-plowing angle β is increased non-linearly, reaches a maximum value at a tail end of the fluke head of the anchor fluke, is greater than 25° but less than 75°, and a bulldozing angle α of the first half-fluke is no less than 15°, wherein, a y-axis is an intersecting line of the normal plane and the plane side wall, a z-axis is perpendicular to the y-axis in the normal plane, a zero O is a midpoint at a bottom edge of the plane side wall, an OXYZ coordinate system is established according to a right-hand rule, an included angle between a tangent line of an intersecting line of the curved side wall and an XOZ plane and an OX-axis is the soil-turning angle β, an included angle of an intersecting line of the curved side wall and the normal plane and an OY-axis is the soil-penetrating angle θ, and a half of a vertex angle of the plane side wall is the bulldozing angle α.
3. The bionic high holding power anchor according to claim 2, wherein an equation of the intersecting line of the first half-fluke and the XOZ plane is z=76.72−0.82x−0.198x.sup.1.5+0.034x.sup.2−0.00112x.sup.2.5.
4. The bionic high holding power anchor according to claim 3, wherein three fluke heads are arranged at equal intervals.
5. The bionic high holding power anchor according to claim 4, wherein the anchor rod is herringbone, a shaft hole is arranged between the adjacent fluke heads, the shaft hole is internally equipped with a hinge shaft connected with the anchor rod, and the anchor fluke is provided with a pin shaft limiting the hinge shaft to move.
Description
BRIEF DESCRIPTION OF THE DRAWINGS
[0016] FIG. 1 is a front view of the present invention.
[0017] FIG. 2 is a side view of the present invention.
[0018] FIG. 3 is a front view of an anchor fluke in FIG. 1.
[0019] FIG. 4 is a B-B sectional view in FIG. 3.
[0020] FIG. 5 is a vertical view of the present invention.
[0021] FIG. 6 is a schematic diagram of a connected portion of an anchor rod and an anchor fluke.
[0022] FIG. 7 is a bionic lead curve graph.
[0023] FIG. 8 is a schematic diagram of a three-dimensional perspective of the anchor fluke.
[0024] FIG. 9 is a structural schematic diagram of the anchor fluke.
DETAILED DESCRIPTION
[0025] As shown in FIG. 1 to FIG. 9, a bionic high holding power anchor according to the present invention includes an anchor rod 3, a suspension clasp 1 coupled with one end of the anchor rod 3 and an anchor fluke 4 hinged with the other end of the anchor rod 3, wherein the suspension clasp 1 is coupled with the anchor rod 3 via a suspension clasp shaft 2, a plurality of fluke heads 5 arranged at equal intervals are extended from a front end of the anchor fluke 4, and preferably, three fluke heads 5 are arranged at equal intervals, fin-like streamlined balance wings 6 are arranged at two sides of the anchor fluke 4; two anchor rods 3 are provided, a shaft hole is arranged between the adjacent fluke heads 5, the axle shaft is internally equipped with a hinge shaft 7 connected with the anchor rod 3, the anchor fluke 4 is provided with a pin shaft limiting the hinge shaft 7 to move; the fluke head is in a shape of triangle-like taper containing a plane side wall ABC and two curved side walls ABD and ACD, the plane side wall ABC is an isosceles triangle, the two curved side walls ABD and ACD are smooth curved surfaces, and the two smooth curved surfaces ABD and ACD are symmetrical around a normal plane AOD of the plane side wall ABC. The fluke head includes a first half-fluke ABOD and a second half-fluke ACOD, the first half-fluke ABOD and the second half-fluke ACOD are symmetric around the normal plane AOD, ensuring that a soil-penetrating angle of the first half-fluke θ∈(22°, 40°), a soil-turning angle β is increased non-linearly, reaches a maximum value at a tail end of the fluke head of the anchor fluke and β∈(25°, 75°). Under the condition of guaranteeing the shape of the curved surface ABD, a bulldozing angle α of the first half-fluke ABOD is no less than 15°, wherein, a y-axis is an intersecting line of the normal plane AOD and the plane side wall ABC, a z-axis is perpendicular to the y-axis in the normal plane AOD, a zero O is a midpoint at a bottom edge of the plane side wall ABC, an OXYZ coordinate system is established according to a right-hand rule, wherein an included angle between a tangent line of an intersecting line of the curved side wall ABD (and/or ACD) and an XOZ plane and an OX-axis is the soil-turning angle β, an included angle of an intersecting line of the curved side wall ABD (and/or ACD) and the normal plane AOD and an OY-axis is the soil-penetrating angle θ, and a half of a vertex angle of the plane side wall ABC is the bulldozing angle α.
[0026] In this embodiment, three longitudinally parallel bionic fluke heads 5 are arranged at the front end of the anchor fluke, and a cross section of the fluke head 5 is as shown in FIG. 4. A three-dimensional modeling of the fluke head 5 is as shown in FIG. 8 and obtained by simulating and modeling the head of guitarfish, the balance wings 6 at two sides of the anchor fluke 4 are obtained by simulating the streamlined pectoral fins at the two sides of the guitarfish, and the sectional dimension of the anchor is increased longitudinally, so that the turning force applied to the anchor is reduced, the entire anti-turning property of the anchor is improved, and a risk of anchor dragging is reduced significantly. Both an upper surface and a lower surface of the anchor fluke 4 are in a structure of slope as shown in FIG. 4, so that the resistance to the bionic high holding power anchor in the process of weighing anchor is lower.
[0027] The lead curve of the bionic plow-shaped fluke head 5 of the high holding power anchor is as shown in FIG. 7, and obtained according to a curve equation (1); the curve 3-1 as shown in FIG. 3 meets the curve equation (1), and a curved structure of the fluke head 5 of the anchor fluke as shown in FIG. 8 is configured for the lead curve according to the curve; the curved surface of the fluke head 5 as shown in FIG. 9 is an anchor fluke working surface, or a curved surface constructed by a horizontal straight element method, including a soil-penetrating angle θ, a soil-turning angle β, and a bulldozing angle α. The higher the soil-penetrating angle θ is increased with the height of the curved surface, the better the soil crushing property is. The soil-turning angle β is increased non-linearly, and reaches a maximum value at a tail end of the fluke head. The higher the value is, the better the soil turning property is. When the anchor fluke works, the anchor fluke 4 accesses to the soil to break ground at the soil-penetrating angle θ and the bulldozing angle α, the soil is turned over towards an over-turning and throwing curved surface along a main cutting surface until covering the previous stroke. As shown in FIG. 9, the bionic anchor fluke cutting head makes the soil-turning angle β increased non-linearly and up to a maximum value at the tail end of the fluke head 5, under a situation of guaranteeing the shape of the cutting curved surface ABD, θ∈(22°, 40°), and β∈(25°, 75°); meanwhile, the anchor fluke has a larger bulldozing angle α of no less than 15°; the two characteristics make the anchor fluke have a good ability to enter the soil in the soil layer, especially in the hard soil layer. The three fluke heads 5 are arranged at equal intervals and have the same size. Compared with the two fluke heads of the common high holding power anchor, the three fluke heads in parallel have better anti-turning property.
z=76.72−0.82x−0.198x.sup.1.5+0.034x.sup.2−0.00112x.sup.2.5 (1)
[0028] In the embodiment, the herringbone anchor rod 3 is obtained by integral casting. Compared with the straight-rod shaped anchor rod of the common high holding power anchor, the longitudinal width of the cross-section of the herringbone anchor rod 3 is increased. A body embedding condition is formed with the participation of the herringbone anchor rod, so that the anchoring force is increased, and the anchor positioning capability is increased. The bionic structure anchor fluke 5 is hinged with the herringbone anchor rod 3. As shown in FIG. 6, the hinge connection is realized via the hinge shaft 7. As shown in FIG. 6, the hinge shaft 7 is matched with the shaft hole 8 inside the anchor fluke 4, the hinge shaft 7 is fixed via a pin shaft 9 as shown in FIG. 6, a radial degree of freedom of the hinge shaft 7 is limited by the pin shaft 9 and the shaft hole 8, and an axial degree of freedom of the hinge shaft 7 is limited by gradual change in the size of the shaft hole. In the entire realization, firstly, the herringbone anchor rod 3 and the anchor fluke 4 are hinged via the hinge shaft 7 and fixed by the pin shaft 9. The front end joint of the herringbone anchor rod 3 is located above the center of the anchor fluke 4, avoiding the anchor from turning during the process of throwing into water, and ensuring that the anchor works at an angle as shown in FIG. 2. The dimension scale of a bionic flow-shaped three-fluke high holding power anchor is as follows, with labels as shown in FIG. 3 and FIG. 4: a length-height ratio of the anchor fluke L:H=5:1, a length-width ratio of the anchor fluke L:S=3:2, and a bionic fluke head proportion D.sub.1:D.sub.2=3:2.
[0029] The above only describes the preferred embodiments of the invention. It should be noted that those having ordinary skills in the art may also make various improvements and polishing without departing from the principle of the invention, which shall all be deemed as the protection scope of the invention.
