JP6955764B2 - Amphibious balance board structure - Google Patents

Description

The present invention relates to a board used on water such as a surfboard and a stand-up paddle (SUP) board (hereinafter referred to as SUP board) (hereinafter collectively referred to as a balance board), which can be used on water as before, and also on the ground surface and the like. On land, it provides an amphibious balance board structure that can be used for physical training such as yoga.

Conventional surfboards are sports that use waves generated on the surface of the water such as the sea, and by riding on an unstable surfboard and balancing it, the waist, crotch, thighs, knees, etc. are trained, and it has a core training effect. In addition, the conventional sapboard is a sport in which a person stands on a large surfboard floating on the surface of the water and uses tools such as oars to row and move on the surface of the water. Like a surfboard, it has a core training effect such as training the waist, crotch, thighs, and knees.

A method of performing trunk training using such a plate-shaped board is disclosed in the following patent documents.

In Patent Document 1, a surfboard type deck, a balance ball having a flat upper surface, and a connecting plate material for being integrally fixed to the lower surface of the surfboard type deck with the upper surface side of the balance ball are provided on land. It discloses a surfboard type balance board structure that can be used for surfing practice and core training.

Utility Model Registration No. 3207318 Gazette

However, Patent Document 1 assumes core training on land, and does not assume that the same core training effect as on land can be obtained even when floating on water.

The present invention has been devised to solve such a problem, and a sap board or the like used for training on water can be used on land, and the same core training can be provided on both water and land. It is intended to provide an amphibious balance board structure.

In the present invention, a swing piece having an inclined outer periphery is projected at a required position on the outer bottom surface of a balance board body used on water like a surfboard or a sapboard, and the surface of the balance board body corresponding to the swing piece position. The position is characterized by an amphibious balance board structure characterized in that a plurality of rough surfaces capable of detecting the foot points of the body axis are formed adjacent to each other.

Further, the swing frame in which the outer peripheral inclined shape, square shape, a disc shape, that is semi-cylindrical shape and a plurality of stages shape or we selected one shape projecting protrusions on the substrate center around inclined It is a feature.

Further, the surface position of the balance board main body is characterized in that a rough surface capable of detecting the foot point of the body axis is divided into four regions .

According to the invention of claim 1, since a swing piece having an inclined outer periphery is projected at a required position on the outer bottom surface of the balance board main body, the swing piece is balanced when used while floating on water. By functioning as a floating body that pushes the board body upward, it can float stably on the water even when a person gets on it, and it is possible to perform core training with peace of mind. In particular, the part where the swing top is installed has more buoyancy than the other parts, so it is easy to understand where to get on the sapboard etc. during core training. Also, when the balance board body is placed on land and used, the balance board body will be in an unstable state floating in the air from the ground with this swing piece as a fulcrum, so it is as if the person riding the balance board body is in an unstable state. You can feel the floating feeling as if you are using this balance board body floating on the water, and you can train your core just by maintaining the riding state. In addition, due to the floating feeling, when the trunk is trained on the balance board body, the same training effect as the trunk training at sea can be expected.
In addition, a plurality of rough surfaces that can detect the foot points of the body axis are formed adjacent to each other at the surface position of the balance board body corresponding to the swing frame position, and the rough surface is divided into four regions. By doing so, it is possible to detect where the balance board body is located without separating the sole of the bare foot from the surface of the balance board body. That is, the user searches for other rough surfaces by arranging a plurality of rough surfaces adjacent to each other and moving the foot with the sole of the bare foot in contact with the surface of the balance board body, so-called sliding feet. You can detect the standing position without causing an unstable state of putting your weight on one leg, and you can easily change your standing position without getting off the surface of the balance board body.

According to the second aspect of the present invention, the swing top having an inclined outer periphery is selected from a square shape, a disk shape, a semi-cylindrical shape, and a multi-stage shape in which a protrusion protrudes from the center of the peripheral inclined substrate. Since it has a single shape, when the balance board is placed on land and used, the floating feeling changes according to the shape of the swinging top, and it swings arbitrarily according to the skill level of the user and the core training location. You can select the shape of the frame. Further, when used on water, the volume of the swinging top becomes a buoyancy to the balance board main body, and the stability of the balance board main body on water can be changed from the shape of the swinging top.
That is, when the swinging top is formed in a square shape, the grounding stability of the balance board main body fluctuates according to the installation location of the swinging top with respect to the bottom surface of the balance board main body on land, so that the stable state is unstable. Various forms can be formed up to the state. Further, on the water, the location where the buoyancy is generated on the balance board main body varies depending on the installation location of the swing top on the bottom surface of the balance board main body, and various forms can be formed from a stable state to an unstable state.
Further, when the swing top is formed in a disk shape, the ground contact stress generated on the outer peripheral surface of the swing top fluctuates according to the minute movements performed by the user on the balance board body to maintain equilibrium on land. do. Therefore, the form of this swing top is constantly changing, and the core training can be performed simply by maintaining the balance on the upper surface of the balance board body. Further, on the water, the swinging top is deformed according to the water flow in the water, and the direction of the buoyancy generated in the balance board main body fluctuates according to the form of the swinging top. Therefore, the balance board body can form an unstable state on the water. The user can perform effective core training simply by riding on the balance board body in this unstable state and maintaining balance.
Further, when the swing piece is formed in a semi-cylindrical shape, the swing direction of the balance board changes depending on the longitudinal direction of the swing piece when it is installed on the bottom surface of the balance board body on land. That is, when the balance board main body and the swing piece are arranged in parallel in the longitudinal direction, the balance board main body can swing in the left-right direction. Further, when the balance board body and the swing piece are arranged in a direction intersecting the longitudinal directions, the balance board can swing in the front-rear direction. By forming the swing piece into a semi-cylindrical shape in this way, the swing direction of the balance board can be arbitrarily adjusted to change the part to be trained by the trunk training.
Further, when the swing pieces are formed in a multi-stage shape, the swing pieces are formed symmetrically in the vertical and horizontal directions on land, and buoyancy is evenly generated in the balance board body to keep the balance board body in a stable state. Can be kept.
Further, when the balance board main body is propelled, the stability of the balance board main body can be arbitrarily changed according to the shape of the swing top that collides with the water flow.
When the swing top is formed in a square shape, the effect differs depending on the mounting position on the bottom surface of the balance board body. When installed from the center of the bottom of the balance board body to the propulsion direction side, the balance board body located on the propulsion side is suspended from the water to reduce the contact area with the water flow, which reduces the resistance due to the water flow and stabilizes it. A state of progress can be formed. In addition, when the balance board body is installed on the bottom surface of the board opposite to the propulsion direction from the substantially central part of the bottom surface of the balance board body, the balance board body on the propulsion side is settled from the water to increase the contact area with the water flow, which hinders the progress. This increases the load on the user and increases the training effect.
When the swinging top is formed in a disk shape, the top is deformed by the water flow generated when the balance board body is propelled. This rocking top fluctuates the direction of the buoyancy generated in the balance board body due to the water flow, and can create an unstable state when the balance board body is propelled. Therefore, efficient core training can be performed by propelling the balance board body in this state.
When the swing top is formed in a semi-cylindrical shape, the water flow resistance varies depending on the direction in which it is attached to the bottom surface of the balance board body. When the semi-cylindrical swing piece is parallel to the longitudinal direction of the balance board body, the flowing water generated when the balance board is propelled is divided into two on the left and right side surfaces of the semi-cylindrical shape when it collides with the swing piece. Therefore, this swing top acts to improve the straightness of the balance board like fins arranged on the back surface of the surfboard in order to improve the straightness of the surfboard, and enables stable straight running. ..
Further, when the semi-cylindrical swing piece and the balance board are arranged in the direction where the longitudinal direction intersects, the flowing water generated when the balance board is propelled flows along the semi-cylindrical peripheral surface when it collides with the swing piece. Then, it is peeled off from the swing top in the vicinity of the peripheral ridgeline. As a result, a buoyancy force is generated rearward and upward with respect to the balance board body, and the traveling direction side of the balance board body sinks from the water to increase the contact area with the water flow. As a result, this swinging top hinders the progress of the balance board body, increases the physical load on the user, and exerts the effect of efficient trunk training.
Further, when the swing piece is formed in a multi-stage shape, the swing piece is formed symmetrically in the front-rear and left-right directions, and the water flow generated when the balance board body is propelled is moved backward along the shape of the swing piece. Distribute. As a result, the propulsion side of the balance board main body is suspended from the water, the contact area between the balance board main body and the water flow is reduced, and stable running is possible.

According to the invention of claim 1 , since a rough surface capable of detecting the foot point of the body axis is divided into four regions at the surface position of the balance board main body, the user of the balance board main body can feel his / her feet. It is possible to detect where the core axis of the body is located on the balance board body without checking. Therefore, the user has the widest operating area in the standing state, does not fluctuate the heavy head position, and can reduce the probability of losing balance on the balance board body.

It is a perspective view which shows the exercise using the sap board main body in embodiment of this invention. It is a top view which shows the sap board main body in embodiment of this invention. It is a bottom view which shows the sap board main body in embodiment of this invention. It is a side view which shows the sap board main body in embodiment of this invention. It is a perspective view which shows the rocking top of the semi-cylindrical shape in embodiment of this invention. It is a figure which shows the rocking top of the rectangular shape in a plan view in embodiment of this invention, (a) is a perspective view, and (b) is a left side view. It is a figure which shows the disk-shaped swing top in embodiment of this invention, (a) is a perspective view, and (b) is a left side view which shows the usage form. It is a figure which shows the swing top of a multi-stage shape in embodiment of this invention, (a) is a perspective view, (b) is a left side view. It is a figure which shows the rough surface of the sap board in embodiment of this invention, (a) is a plan view which shows the convex surface of substantially hemisphere, (b) is the plan view which shows the convex surface of substantially square columnar. (C) is a plan view showing a substantially triangular convex surface in a plan view, and (d) is a plan view showing a continuous concave-convex cross-sectional shape having a substantially rectangular shape. It is a left side view which shows the usage form of the sap board in embodiment of this invention, (a) is a figure which shows the equilibrium state, and (b) is a figure which shows the swing to the left and right.

The gist of the present invention is that the amphibious balance board structure is characterized in that a swing piece having an inclined outer periphery is projected at a required position on the outer bottom surface of the balance board body, and the outer periphery is inclined. The swinging top is characterized in that it has a single shape selected from a square shape, a disk shape, a semi-cylindrical shape, a multi-stage shape in which a protrusion protrudes from the center of the substrate in a peripheral inclined shape, and the like. The feature is that a rough surface is formed on the surface position of the balance board body corresponding to the above so that the foot point of the body axis can be sensed by the sole of the bare foot.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings, taking a sap board as an example.

As shown in FIGS. 1 and 3, the present invention includes a sapboard main body 10, a rough surface 20 formed at a substantially central portion of the front surface of the sapboard main body 10, and a substantially central portion of the bottom surface of the sapboard main body 10. It is composed of a mounting / fixing portion 30 formed in the above and a swing piece 40 fixed to the mounting / fixing portion 30.

As shown in FIG. 2, the sapboard main body 10 is formed in a substantially triangular shape that is tapered from the substantially central portion in the plan view toward the tip portion 13, and the rear end portion 14 is substantially formed from the substantially central portion in the plan view. It is formed in a shape. A plurality of fixing bands 12 are arranged on the outer peripheral edge of the front surface of the sap board main body 10.

Each fixing band 12 has a substantially rectangular shape in a plan view, and both ends in the longitudinal direction are fixed to the sapboard main body 10 with an adhesive. Is forming.

The mounting band 16 selects one point facing each other from the left and right sides of the sapboard body 10, that is, two arbitrarily facing fixed bands 12 among the plurality of fixed bands 12 arranged on the peripheral edge of the sapboard body 10, and the fixing band 16 It is inserted through the ring-shaped portions 15 and 15 of 12 and 12, and is attached to the sapboard main body 10 so as to go around in the left and right side directions. In this embodiment, the mounting band 16 formed on the front end 13 side of the sapboard main body 10 is referred to as the mounting band 16a, and the mounting band 16 formed on the rear end 14 side is referred to as the mounting band 16b.

Each of the mounting bands 16a and 16b is provided with a plurality of ring-shaped loop portions 17 at equal intervals, and the loop portions 17 are mounted so as to be arranged on the front surface side of the sapboard main body 10. The user H connects one end of the rubber band 18 described later to any of the loop portions 17 of the mounting band 16a of the sapboard main body 10, and forms the other end on the rear end 14 side of the sapboard main body 10. It is tied to any of the loop portions 17 of the attached mounting band 16b.

As shown in FIG. 1, the rubber band 18 is formed of a flexible elastic body, and has a substantially columnar grip portion 19 at a substantially central portion.

Further, the sapboard main body 10 is formed in a substantially rectangular shape in a side view as shown in FIG. Conventionally, a board used on water has a shape that is curved upward from a substantially central portion to a tip portion of the board in order to reduce the resistance of waves during traveling. By forming the tip of the board in such a shape, the load area of water applied to the board is reduced and the stability of the board is improved. However, in the present invention, the bottom surface side of the sapboard main body 10 is a flat surface having substantially the same plane. Therefore, when traveling toward the tip portion 13, the resistance of water is applied to the entire tip portion 13 of the sapboard main body 10, and the resistance force of water during traveling increases. As a result, when the user H travels the same distance using the sap board main body 10 as compared with the board whose tip is curved, the load on the body increases. Therefore, it is possible to exert a more efficient training effect than before. Further, when the sap board main body 10 is used while floating on the water surface, the bottom surface of the sap board main body 10 forms a uniform buoyancy, and the board main body 10 forms a surface parallel to the water surface without tilting back and forth and left and right. , User H can carry out core training in a stable state.

Further, as shown in FIG. 5, a mounting and fixing portion 30 having a substantially rectangular shape in a plan view is formed in a substantially central portion of the bottom surface of the sapboard main body 10. The mounting fixing portion 30 mounts a swing piece 40, which will be described later. The mounting and fixing structure of the mounting and fixing portion 30 and the swinging piece 40 is composed of a surface fastener 31, and the loop surface portion 32 of the surface fastener 31 is attached to the mounting and fixing portion 30 to the sapboard main body 10 of the swinging piece 40. The hook surface portion 33 of the hook-and-loop fastener 31 is attached to the installation surface side of the above.
The mounting and fixing structure is a hook-and-loop fastener 31 in the present embodiment, but in the present invention, it is sufficient that the swing piece 40 can be mounted and fixed to the sapboard main body 10, and it is difficult to corrode even if it comes into contact with water or seawater. The swing piece 40 may be fixed by a coated wood screw or the like. Further, the shape of the hook-and-loop fastener 31 can be arbitrarily changed depending on the shape of the swing top attached to the sapboard main body 10, and is not limited to the rectangular shape in the plan view shown in the drawing of the present embodiment.

The swinging piece 40 can have various forms depending on the purpose. For example, the swinging piece 50 having a substantially rectangular shape in a plan view and a substantially trapezoidal shape in a plan view, and a semicircle in a plan view having a substantially circular shape in a side view. Approximately hemispherical oscillating piece 60 in a circular shape, approximately semi-cylindrical oscillating piece 70 in a semicircular shape in a front view, and a multi-stage oscillating piece in a lateral view with a rectangular shape in a plan view 80 and the like can be attached and used.

(First Example)
As shown in FIGS. 6 (a) and 6 (b), the swing piece 50 is formed in a substantially square columnar shape having a substantially rectangular shape in a plan view and a substantially trapezoidal shape in a side view. A hook-and-loop fastener (not shown) is arranged on the bottom surface of the swing piece 50, and the hook-and-loop fastener is engaged and fixed to the hook-and-loop fastener 31 of the sapboard main body 10. Therefore, when the rocking piece 50 touches the ground, the upper surface portion 52 formed on the top surface of the rocking piece 50 and having a substantially flat side view can be used as the grounding surface. By forming in this way, the user H can relatively easily maintain the equilibrium even if he / she gets on the sapboard main body 10 when using it on land G.

Further, the swing piece 50 generates a buoyancy force that pushes up the sapboard main body 10 when used on water. Therefore, the position of the buoyancy generated in the sapboard main body 10 can be changed by arbitrarily changing the mounting position of the swing piece 50 to the mounting fixing portion 30. That is, when the swing piece 50 is provided on the front end 13 side of the sap board main body 10, the front end 13 side of the sap board main body 10 is separated from the water surface and the rear end 14 side is settled in water. Further, when the swing piece 50 is provided at the substantially central portion of the sapboard main body 10, the buoyancy of the sapboard main body 10 pushes up the substantially central portion of the sapboard main body 10 in a plan view by the buoyancy of the swing piece 50. It occurs and can stabilize the sapboard body 10 on the water. Further, when the swing piece 50 is provided on the rear end 14 side of the sap board main body 10, the tip 13 side of the sap board main body 10 is settled in water and the rear end 14 side is separated from the water surface.

(Second Example)
Further, as shown in FIG. 7A, the swing piece 60 is composed of a substantially hemispherical and flexible elastic body 61 and a disk 62 having a substantially circular shape in a plan view. The disk 62 has a hook-and-loop fastener arranged on the lower surface thereof, and is engaged and fixed with the hook-and-loop fastener 31 arranged on the bottom surface of the sapboard main body 10. By fixing the swing piece 60 to the sapboard main body 10 in this way, the elastic body 61 can be used as a ground plane. The peripheral surface portion of the elastic body 61 is deformed into an arbitrary stable shape as shown in FIG. 7B when stress is applied from the floor surface. However, the stress applied to the elastic body 61 from the floor surface is constantly fluctuating due to the minute operation performed by the user H riding on the sapboard main body 10 to maintain equilibrium. Therefore, the elastic body 61 constantly changes its shape in a fluid manner, and it is difficult to form a stable shape. Therefore, even if the user H rides on the upper part of the sapboard main body 10 and maintains a stable standing state, a sufficient trunk training effect can be exhibited.

Further, the swing piece 60 is constantly deformed according to the direction of the water pressure applied to the elastic body 61 even when used on water. As a result, the direction of the buoyancy generated in the sapboard main body 10 also constantly changes. Therefore, the elastic body 61 has a form that is difficult to stabilize even on water, and an effective trunk training effect can be exhibited only by maintaining the standing state on the sapboard main body 10 as in the state of being placed on the land G.

(Third Example)
Further, as shown in FIGS. 3 and 10A, the swing piece 70 forms a semi-cylindrical shape by connecting a flat surface portion 72 having a substantially rectangular shape in a plan view and a peripheral surface portion 71 having a substantially semicircular shape in a side view. ing. The swing piece 70 produces different effects depending on the orientation in the longitudinal direction when it is attached to the sapboard main body 10.
Specifically, when the swing piece 70 and the sapboard body 10 are installed in parallel in the longitudinal direction, the sapboard body 10 swings according to the position of the center of gravity of the user H as shown in FIG. 10B. It swings in the left-right direction about the top 70 as an axis.
Further, when the swing piece 70 and the sapboard body 10 are installed in a direction intersecting the longitudinal directions, the sapboard body 10 swings in the front-rear direction with the swing piece 70 as an axis according to the position of the center of gravity of the user H. ..
In this way, the swing piece 70 can have a different swing direction depending on the longitudinal direction when it is attached to the sapboard main body 10, and can arbitrarily maintain equilibrium according to the trunk portion to be trained requested by the user H. You can choose the direction.

Further, the swing piece 70 exerts a different effect when used by floating on water depending on the orientation of the swing piece 70 in the longitudinal direction when it is attached to the sapboard main body 10.
That is, when the swing piece 70 and the sapboard body 10 are installed in parallel in the longitudinal direction, the sapboard body 10 swings in the left-right direction with the swing piece 70 as an axis as in the land G.
Further, when the longitudinal direction of the swing piece 70 is arranged in a direction intersecting the longitudinal direction of the sapboard body 10, the sapboard body 10 swings in the front-rear direction with the swing piece 70 as an axis as in the land G.

Further, when the swing piece 70 is attached to the sapboard main body 10, it exerts a different effect when traveling on the water in the longitudinal direction of the sapboard body 10, depending on the orientation of the swing piece 70 in the longitudinal direction.
That is, when the swing piece 70 and the sapboard body 10 are installed in parallel in the longitudinal direction, the swing piece 70 functions like a fin of a surfboard to improve the straightness of the sapboard body 10.
Further, when the swing piece 70 and the sapboard main body 10 are installed so as to intersect the longitudinal directions, the flowing water in contact with the swing piece 70 passes through the peripheral surface portion 71 of the swing piece 70 and is the peripheral surface of the peripheral surface portion 71. It reaches the ridgeline portion 75. That is, when the running water comes into contact with the peripheral surface portion 71, the sapboard main body 10 is pushed up diagonally backward and upward, and a drag force is generated in the traveling direction. Therefore, the load due to the water flow to the user H increases and a high training effect can be exhibited as compared with the case where the swing piece 70 and the sapboard main body 10 are installed in parallel in the longitudinal direction.

(Fourth Example)
Further, in the fourth embodiment, the swing piece 40 is formed of a multi-stage swing piece 80 as shown in FIG. The swing piece 80 is composed of a base 81 having a substantially rectangular shape in a plan view and a substantially dome shape in a side view, and a flat plate 82 having a substantially square shape in a plan view connected to a substantially central portion of the base 81. The swing piece 80 is provided with a hook-and-loop fastener at a substantially central portion of the bottom surface of the base 81, and the surface fastener is engaged and fixed to a surface fastener 31 formed at a substantially central portion of the bottom surface of the sapboard main body 10. With such a configuration, the ground contact surface with the land G is configured to be a flat upper surface portion 83 of the flat plate 82.

When the swing piece 80 is mounted on the land G and used, it forms a flat upper surface portion 83 having no unevenness like the swing piece 50, and it is easy to use the upper surface portion 83 as a ground plane. Can be balanced.
Further, when the swing piece 80 is used on water, when the user H gets on the sapboard main body 10, buoyancy corresponding to the volume forming the base 81 and the flat plate 82 is generated in the sapboard main body 10.
Since the swing top 80 has a symmetrical shape in the front-rear direction and left-right symmetry, when it is floated on water, buoyancy is evenly generated upward with respect to the entire bottom surface of the sapboard body 10, and the sapboard body 10 can be kept in a stable state. ..
Further, when the sapboard main body 10 advances, the running water flows toward the flat plate 82 side along the dome shape of the base 81, and a stress is generated to move the sapboard main body 10 diagonally backward and upward. Therefore, due to this diagonally rearward and upward resistance force, it becomes difficult for the user H to advance the sapboard main body 10, and the effect of trunk training is improved as compared with the case where the normal sapboard main body 10 is advanced.

Further, as shown in FIG. 2, the sapboard main body 10 forms a rough surface 20 having a substantially rectangular shape in a plan view at a substantially central portion of the front surface so that a body axis foot point having a substantially rectangular shape in a plan view can be detected. doing.

The rough surface 20 is formed in a substantially rectangular shape in a plan view, and the upper surface of the rough surface 20 is divided into four regions: a front right region 21, a rear right region 22, a front left region 23, and a rear left region 24. It is formed, and different uneven surface shapes for non-slip are formed.

As shown in FIG. 9A, the front right region 21 forms a substantially hemispherical convex surface 25 at the grid-like intersection. As shown in FIG. 9B, the rear right region 22 forms a substantially square columnar convex surface 26 at the grid-like intersection. As shown in FIG. 9C, the front left region 23 arbitrarily forms a convex surface 27 having a substantially triangular shape in a plan view. As shown in FIG. 9D, the rear left region 24 continuously forms a convex surface 28 having a substantially rectangular side view.

By setting the rough surface 20 of the sapboard main body 10 as four different regions in this way, the user H can recognize the standing position on the sapboard main body 10 without checking his / her feet. Therefore, the user H does not need to move the head on the sapboard main body 10 to check the standing position, and determines the point to be the axial foot of the body by the uneven shape of the rough surface 20 sensed by the sole of the bare foot. , Can be kept parallel.
In the present embodiment, the four regions forming the rough surface 20 have uneven surface shapes having different shapes, but the rough surface is only required if the user H can recognize the standing position on the sapboard main body 10. Of the four surfaces of 20, for example, the front right region 21 and the rear left region 24 are defined as a substantially hemispherical convex surface 25 at the grid-like intersection shown in FIG. 9A, and the front left region 23 and the rear right region 22 are designated. As shown in FIG. 9B, there may be two regions having a substantially square columnar convex surface 26 at the grid-like intersection.

The sapboard main body 10 in the present embodiment is configured as described above, and training for the user H when the oscillating piece 40 is grounded according to the shape of the oscillating piece 40 attached to the back surface of the sapboard main body 10. The effect is different.

For example, in the case of the swing piece 50, the sense of balance required for the user H riding on the sapboard main body 10 differs depending on the area of the flat surface having a substantially rectangular shape in the plan view of the upper surface 51 to be grounded. That is, as the area of the upper surface 51 shifts from the large shape to the small shape, the stability of the sapboard main body 10 decreases, and it becomes difficult to maintain equilibrium, resulting in more advanced trunk training.

Further, in the case of the swing piece 60, since the peripheral surface portion 71 to be grounded is formed of an elastic body, the shape of the hemispherical peripheral surface portion 71 changes when the user H rides on the upper surface of the sapboard main body 10. At that time, the user H finely adjusts the muscles in order to maintain the equilibrium, and the trunk can be trained by the adjustment operation for maintaining the equilibrium.

Further, in the case of the swing piece 70, when the longitudinal direction of the swing piece 70 is attached to the sapboard main body 10, the longitudinal direction of the swing piece 70 is parallel to or intersects with the longitudinal direction of the sapboard body 10. Depending on the situation, the part to be trained during core training changes.
Specifically, when the swing piece 70 and the sapboard main body 10 are arranged so as to be parallel to each other, the circumferential direction of the peripheral surface portion 71 is the left-right direction of the sapboard main body 10, and the user H is the user H. The balance is maintained against the lateral swing of the board body 10.
Further, when the longitudinal direction of the swing piece 70 is arranged so as to intersect the longitudinal direction of the sapboard main body 10, the circumferential direction of the peripheral surface portion 71 is the front-rear direction of the sapboard main body 10, so that the user H The equilibrium is maintained against the swing of the board body 10 in the front-rear direction.

Further, in the case of the swing piece 80, the sense of balance required for the user H riding on the sapboard main body 10 differs depending on the area of the flat plate 82 having a substantially rectangular shape in a plan view, which is grounded like the swing piece 50. Has a similar training effect.

Further, the load of trunk training when traveling on the water can be adjusted according to the shape of the swing piece 40 attached to the back surface of the sapboard main body 10.

For example, in the case of the swing piece 50, the flowing water that comes into contact with the side surface of the swing piece 50 by moving the sapboard main body 10 flows to the upper surface 51 side of the swing piece 50. As a result, the sapboard body 10 generates a buoyancy diagonally rearward and upward toward the rear end 14 side due to running water, and separates the tip 13 side from the water surface to reduce the contact area between the sapboard body 10 and the water surface. It is possible to form a form that easily progresses and reduce the load on the body.

Further, for example, in the case of the swing piece 60, when the flowing water generated by moving the sapboard main body 10 comes into contact with the swing piece 60, the elastic body 61 forming the swing piece 60 is deformed. The deformation of the elastic body 61 changes the direction of the buoyancy generated in the sap board main body 10 to form an unstable state, and hinders the progress of the board main body 10. Therefore, the user H can improve the trunk training effect of the body in combination with the operation of maintaining equilibrium on the sapboard main body 10 and the difficulty of advancing the sapboard main body 10.

Further, for example, in the case of the swing piece 70, the effect differs depending on the mounting direction in the longitudinal direction when the swing piece 70 is installed on the sapboard main body 10.
Specifically, when the longitudinal direction of the swing piece 70 and the sapboard body 10 are parallel to each other, the swing piece 70 acts like a fin of a surfboard to improve the straightness of the sapboard body 10. do.
Further, when the longitudinal direction of the swing piece 70 and the sapboard main body 10 are set to intersect with each other, the flowing water flows along the peripheral surface portion 71 of the swing piece 70 toward the peripheral ridge line portion 75. As a result, the sapboard main body 10 can generate a drag force in the rear-upward direction and separate the tip portion 13 side of the sapboard main body 10 from the water to form a stable traveling form.

Further, for example, in the case of the swing piece 80, the flowing water generated by moving the sap board body 10 flows to the flat plate 82 side along the dome shape of the base 81 forming the swing piece 80, and flows to the board body 10. Generates buoyancy diagonally upward. As a result, the moving tip side of the board body 10 is separated from the water surface due to running water, and the installation area with the water surface is reduced so that the board body 10 can proceed smoothly.

An example of training by placing the above-mentioned sap board main body 10 on the land G will be described with reference to FIG.
First, the fixing bands 12 and 12 are arranged near the front and rear ends of the peripheral edge of the sapboard main body 10.
A mounting band 16 is inserted through the ring-shaped portions 15 and 15 of the fixing bands 12 and 12, and each loop portion 17 is arranged so as to be arranged on the upper surface of the sapboard main body 10.
One end of the training rubber band 18 is attached to the loop portion 17 formed on the tip portion 13 side of the sapboard main body 10, and rubber is attached to the loop portion 17 arranged on the rear end portion 14 side of the sapboard main body 10. Attach the other end of the band 18.
The rubber band 18 is formed with a grip portion 19 for pulling the rubber band 18 during training.
Next, the hook surface portion 33 of the surface fastener 31 arranged on the lower surface of the swing piece 70 is brought into contact with the loop surface portion 32 of the surface fastener 31 of the mounting and fixing portion 30 arranged at substantially the center of the bottom surface of the sapboard main body 10. Fix with.
Next, the user H stands on the rough surface 20 formed on the upper surface of the sapboard main body 10 as shown in FIG. 1, and grips the grip portions 19 and 19 with the left and right palms, respectively.
After that, the user H extends the grip portions 19 and 19 upward from the shoulder, so that the elastic force of the rubber band 18 becomes a load on the user H and exerts a training effect.
When the above training method is carried out on a stable land G, the upper body of the user is trained. However, in the present invention, as shown in FIG. 10B, the lower half of the body is also in an unstable state due to the action of the swing piece 40 (the swing piece 70 in this embodiment) arranged on the bottom surface of the sapboard main body 10. By keeping the sapboard body 10 in equilibrium with respect to the ground, it is possible to train the lower body at the same time as training the upper body. Moreover, due to the action of the swing piece 40, it is possible to form an unstable state on the water while training on land G, and to train the trunk that is difficult to train by normal training.

It should be noted that the present invention is not limited to the above-described embodiment, and is disclosed in the configurations in which the configurations disclosed in the above-described embodiments are replaced with each other or the combinations are changed, known inventions, and the above-described embodiments. It also includes configurations in which the configurations are replaced with each other or the combinations are changed. Further, the technical scope of the present invention is not limited to the above-described embodiment, but extends to the matters described in the claims for utility model registration and their equivalents.

H User G Ground 10 Sapboard body 11 Fixed area 12 Fixed band 13 Tip part 14 Rear end part 15 Ring-shaped part 16 Mounting band 17 Loop part 18 Elastic body 19 Handle 20 Rough surface 21 Front right area 22 Rear right area 23 Front left area 24 Rear left area 30 Mounting fixing part 31 Hook-and-loop fastener 32 Loop surface part 33 Hook surface part 40 Swing piece 50 Swing piece 52 Top surface part 60 Swing piece 61 Elastic body 62 Disc 70 Swing piece 71 Peripheral surface part 72 Flat part 75 Peripheral surface ridge 80 Swing piece 81 Base 82 Flat plate 83 Top surface

Claims (2)

A swing piece with an inclined outer periphery is projected at the required position on the outer bottom surface of the balance board body used on water like a surfboard or sapboard, and the body is at the surface position of the balance board body corresponding to the swing piece position. An amphibious balance board structure characterized in that a plurality of rough surfaces capable of sensing a shaft foot point are formed adjacent to each other, and the rough surfaces are divided and formed into four regions. The rocking top having an inclined outer periphery is a shape selected from a square shape, a disk shape, a semi-cylindrical shape, and a multi-stage shape in which a protrusion protrudes from the center of the peripheral inclined substrate. The amphibious balance board structure according to item 1.

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