TWM628705U - Underwater obstacle facility for diving training and competition - Google Patents

Abstract

An underwater obstacle facility for diving training and competition, suitable for providing an infrastructure in a confined water, includes a horizontal traversing unit, a controller and two laser light pattern generators. The horizontal crossing unit is fixed on the configuration plane of the basic structure and provided with a linear movement space. The linear direction of the linear motion space and the direction of gravity are perpendicular to each other. These laser light pattern generators are used to project different laser light patterns on the infrastructure. These laser light patterns simulate a flipping unit and an arc-shaped crossing group respectively, and the arc-shaped crossing group is located between the horizontal crossing unit and the flipping unit. The controller is electrically connected to the laser light pattern generators to activate the laser light pattern generators.

Description

Underwater obstacles for diving training and competition

This work is about an underwater obstacle facility for training and competition, especially an underwater obstacle facility for diving training and competition.

By definition, diving, especially technical diving, originally refers to activities that go below the surface, such as underwater exploration, salvage, repair, and underwater engineering. In today's living society, due to the continuous improvement of diving equipment and the continuous promotion of training methods, diving has developed into activities such as physical exercise or leisure and entertainment.

However, in order to enable more people to get more professional teaching, training and competition, it is an imperative solution to set up suitable obstacle facilities for underwater training even under the consideration of limited space and safety.

Therefore, how to develop a solution to improve the above-mentioned defects and inconveniences is an urgent and important issue for the relevant industry at present.

This creation proposes an underwater obstacle facility for diving training and competition to solve the problems of the prior art.

According to an embodiment of the present invention, the underwater obstacle facility for diving training and competition is suitable for providing an infrastructure in confined waters, and the underwater obstacle facility for diving training and competition includes a horizontal crossing unit, a first laser generator, a second laser generator and a controller. The horizontal crossing unit is fixed on one of the configuration planes of the basic structure, and has a linear movement space. The linear direction of the linear motion space and the direction of gravity are perpendicular to each other. The first laser generator is fixed on the base frame, and is used for projecting a first laser light pattern on the base frame. The first laser light pattern simulates a three-dimensional flip unit, and the three-dimensional flip unit maintains a first distance from a side wall of the base structure. The second laser generator is fixed on the base frame, and is used for projecting a second laser light pattern on the base frame. The second laser light pattern simulates a three-dimensional arc-shaped crossing group with an arc-shaped movement space, and the three-dimensional arc-shaped crossing group is between the horizontal crossing unit and the three-dimensional turning unit. The controller is electrically connected to the first laser generator and the second laser generator for activating the first laser generator and the second laser generator.

According to one or more embodiments of the present invention, in the above-mentioned underwater obstacle facility for diving training and competition, the three-dimensional arc-shaped traversing group further includes a plurality of column-shaped three-dimensional units. These columnar three-dimensional units are formed at intervals on the disposition plane of the base frame. There is a crossing space between any two adjacent columnar three-dimensional units, and the crossing space jointly defines an arc-shaped movement space.

According to one or more embodiments of the present invention, in the above-mentioned underwater obstacle facility for diving training and competition, the three-dimensional turning unit further includes at least one horizontal column three-dimensional unit. The straight line direction of the horizontal column three-dimensional unit and the direction of gravity are perpendicular to each other.

According to one or more embodiments of the present invention, in the above-mentioned underwater obstacle facility for diving training, the underwater obstacle facility further includes a third laser generator. The third laser generator is fixed on the base frame and is electrically connected to the controller for projecting a third laser light pattern on the base frame. The third laser light pattern simulates an indicating rotary three-dimensional unit. Indicates that the rotating three-dimensional unit is located on the configuration plane of the base frame, and maintains a second distance from the side wall of the base frame. Indicates that the direction of the straight line of the rotating solid unit and the direction of gravity are parallel to each other.

According to one or more embodiments of the present invention, the underwater obstacle facility for diving training and competition further includes an athletic field. The arena includes at least one fourth laser generator. The fourth laser generator is fixed on the base frame and is electrically connected to the controller for projecting a fourth laser light pattern on the base frame, and the fourth laser light pattern simulates at least one three-dimensional goal unit.

According to one or more embodiments of the present invention, in the above-mentioned underwater obstacle facility for diving training, the horizontal crossing unit further includes a plurality of first hollow rings. The first hollow rings are arranged at intervals on the configuration plane of the infrastructure. Each of the first hollow rings has a first opening. The first openings of the first hollow ring body are aligned with each other to jointly define a linear motion space. The minimum linear distance from each of the first openings to the configuration plane of the base structure is the same.

According to one or more embodiments of the present invention, the underwater obstacle facility for diving training and competition further includes a lifting and traversing unit. The lift-through unit is fixed on the configuration plane on the base frame, and has a wave-shaped channel.

According to one or more embodiments of the present invention, in the above-mentioned underwater obstacle facility for diving training and competition, the lifting and traversing unit further includes a plurality of second hollow rings. The second hollow rings are arranged at intervals on the configuration plane of the infrastructure. Each of the second hollow rings has a second opening. The second openings do not have the same axis, and jointly define a wave-shaped channel, and the minimum linear distances between the second openings and the disposition plane of the base structure change periodically.

According to one or more embodiments of the present invention, the underwater obstacle facility for diving training and competition further includes an oblique crossing unit. The oblique crossing unit is fixed on the other side wall of the base frame and has an oblique movement space. The linear direction of the oblique motion space intersects with the direction of gravity.

According to one or more embodiments of the present invention, in the above-mentioned underwater obstacle facility for diving training and competition, the oblique crossing unit includes a plurality of third hollow rings arranged at intervals. Each of the third hollow rings includes a third opening, and the third openings of the third hollow rings do not have the same axis, and together define the above-mentioned oblique movement space.

In this way, through the above-mentioned structure, users can obtain more professional teaching, training and competition in an environment with limited space and safety considerations, thereby improving diving skills.

The above descriptions are only used to describe the problems to be solved by the present creation, the technical means for solving the problems, and the effects produced by them.

Plural implementations of the present invention will be disclosed in the drawings below. For the sake of clarity, many practical details will be described together in the following description. However, those skilled in the art should appreciate that these practical details are not necessary in some embodiments of the present invention and should not be used to limit the present invention. In addition, for the purpose of simplifying the drawings, some well-known structures and elements will be shown in a simple and schematic manner in the drawings. In addition, for the convenience of the reader, the size of each element in the drawings is not drawn according to the actual scale.

1A and 1B are consecutive schematic diagrams of underwater obstacle facilities for diving training and competition purposes according to an embodiment of the present invention. As shown in Figures 1A and 1B, underwater obstacle installations for diving training and competition purposes are suitable for providing a confined water infrastructure 10. The confined water generally refers to a swimming pool or a calm open water dive site, and the infrastructure 10 can be used for general swimming, diving and professional diving training, such as rivers, lakes, indoor or outdoor swimming pools, etc., but not as such. limit. Taking an indoor swimming pool as an example, the infrastructure 10 has a bottom surface 11 and a plurality of side walls 12 . The bottom surface 11 is connected to the side walls 12 , and the side walls 12 and the bottom surface 11 together surround a deep diving tank 14 , that is, the bottom surface 11 is the deepest part of the deep diving tank 14 .

The underwater obstacle facility for diving training and competition includes a horizontal crossing unit 100 , a first laser generator 200 , a second laser generator 300 and a controller 800 . The horizontal traversing unit 100 is located in the deep diving tank 14, and is fixed on one of the configuration planes in the deep diving tank 14, such as the bottom surface 11 described above, however, the present invention is not limited to this. The horizontal traversing unit 100 has a linear motion space 120 for the diver D to perform training and teaching of horizontal linear motion at the same height in the linear motion space 120 . The linear direction 121 of the linear motion space 120 and the gravity direction G are perpendicular to each other. The first laser generator 200 is fixed on the base structure 10 for projecting a first laser light pattern into the deep diving tank 14 . The first laser light pattern simulates a three-dimensional flip unit 210, and the three-dimensional flip unit 210 maintains a first distance A1 with a side wall 12 of the deep diving tank 14, so that the diver D can perform underwater flipping training at the first distance A1 and teaching. The second laser generator 300 is fixed on the base structure 10 for projecting a second laser light pattern into the deep diving tank 14 . The second laser light pattern simulates a three-dimensional arc-shaped crossing group 310. The three-dimensional arc-shaped crossing group 310 is located between the horizontal crossing unit 100 and the three-dimensional turning unit 210, and has an arc-shaped movement space 330 for the diver D to The training and teaching of arc-shaped movements of the same height are carried out in the shaped exercise space 330 . The controller 800 is electrically connected to the first laser generator 200 and the second laser generator 300 to activate the first laser generator 200 and the second laser generator 300 in a sequence. For example, the controller 800 first starts the second laser generator 300 , and after the diver D passes through the arc-shaped movement space 330 , the controller 800 turns off the second laser generator 300 and starts the first laser generator 200 . After the diver D passes, the controller 800 turns off the first laser generator 200 . However, the present creation is not limited to this order.

In this way, through the above-mentioned structure, users can obtain more professional teaching, training and competition in an environment with limited space and safety considerations, thereby improving diving skills.

More specifically, the horizontal crossing unit 100 further includes a plurality of first hollow rings 110 . The first hollow rings 110 are arranged at intervals on the arrangement plane of the infrastructure 10 (eg, the bottom surface 11 of the deep diving tank 14 ). Each of the first hollow annular bodies 110 includes a first annular body 111 and a first opening 112 . The first opening 112 penetrates the first annular body 111 . The first annular bodies 111 are fixedly erected on the disposition plane of the base structure 10 , and the first openings 112 of the first annular bodies 111 are coaxial and aligned with each other, so as to jointly define the linear motion space 120 . In other words, the minimum linear distance 113 from the axis of each first opening 112 to the disposition plane of the base structure 10 is the same.

The three-dimensional arc-shaped crossing group 310 further includes a plurality (at least three) of columnar three-dimensional units 311 . The columnar three-dimensional units 311 are arranged at intervals on the arrangement plane of the infrastructure 10 (eg, the bottom surface 11 of the deep diving tank 14 ). The long axis direction 312 of each columnar solid unit 311 is parallel to the above-mentioned gravity direction G. As shown in FIG. There is a passing space 320 between any two adjacent columnar three-dimensional units 311 . These passing spaces 320 together define the above-mentioned arc-shaped movement space 330 . In other words, the second laser generator 300 projects the three-dimensional patterns of the columnar three-dimensional units 311 into the deep diving tank 14 . Therefore, the diver D can perform the training and teaching of the arc-shaped movement in the arc-shaped movement space 330 along the columnar three-dimensional units 311 . The three-dimensional turning unit 210 further includes at least one horizontal column three-dimensional unit 211 . In other words, the first laser generator 200 further projects the three-dimensional pattern of the horizontal column three-dimensional unit 211 into the deep diving tank 14 . The linear direction 212 of the horizontal column three-dimensional unit 211 is perpendicular to the direction G of gravity. Therefore, the diver D can perform the training and teaching of turning in the water at the first interval A1 around the horizontal column three-dimensional unit 211 .

Figures 2A and 2B are consecutive schematic diagrams of the underwater obstacle facility for diving training and competition purposes according to an embodiment of the present invention. As shown in FIG. 2A and FIG. 2B , on the basis of the above-mentioned embodiment, the underwater obstacle facility for diving training further includes a third laser generator 400 , a lifting and traversing unit 500 and an oblique traversing unit 600 . . The third laser generator 400 is fixed on the infrastructure 10 and is electrically connected to the controller 800 for projecting a third laser light pattern into the deep diving tank 14 . The third laser light pattern simulates an indicating rotation stereo unit 410 . Indicates that the rotating three-dimensional unit 410 is projected on the configuration plane of the deep diving tank 14 . More specifically, it is indicated that the rotating three-dimensional unit 410 has a third column-shaped three-dimensional pattern 420 . The third columnar three-dimensional pattern 420 is erected on the configuration plane of the base frame 10 (eg, the bottom surface 11 of the deep diving tank 14 ), and maintains a second distance A2 with the side wall 12 of the base frame 10 . A linear direction 421 of the third columnar three-dimensional pattern 420 and the gravity direction G are parallel to each other. Therefore, the diver D can perform the training and teaching of underwater rotation around the third columnar three-dimensional pattern 420 at the second interval A2. In the present embodiment, the instructed rotating three-dimensional unit 410 is located between, for example, the three-dimensional arc-shaped crossing group 310 and the side wall 12 of the base structure 10 , however, the present invention is not limited to this.

The elevating and traversing unit 500 is fixed on the configuration plane (such as the bottom surface 11 of the deep diving tank 14 ) on the basic structure 10 , and has a wave-shaped channel 520 for the diver D to perform underwater lifting and lowering of height changes in the wave-shaped channel 520 Cross-training and teaching.

More specifically, the lift-through unit 500 further includes a plurality of second hollow rings 510 . The second hollow rings 510 are arranged at intervals on the arrangement plane of the infrastructure 10 (eg, the bottom surface 11 of the deep diving tank 14 ). Each of the second hollow annular bodies 510 includes a second annular body 511 and a second opening 512 . The second opening 512 penetrates the second annular body 511 . The second annular bodies 511 are fixedly erected on the configuration plane of the infrastructure 10 (eg, the bottom surface 11 of the deep diving tank 14 ), but the second openings 512 of the second annular bodies 511 do not have the same axis, so as to The aforementioned wave-shaped channel 520 is collectively defined. In other words, the minimum linear distances 521 of the second openings 512 to the disposition plane of the base structure 10 change periodically. In other words, the minimum linear distance 521 from the axis of each second opening 512 to the disposition plane of the base structure 10 gradually increases and then decreases. In the present embodiment, the lift crossing unit 500 is, for example, located between the three-dimensional arc-shaped crossing group 310 and the horizontal crossing unit 100 , however, the present invention is not limited to this.

The oblique crossing unit 600 is fixed on the other side wall 13 of the base structure 10, and has an oblique movement space 620, so that the diver D can perform training and oblique crossing in water with varying heights in the oblique movement space 620. teaching. The linear direction 621 of the oblique motion space 620 intersects with the direction G of gravity.

More specifically, the oblique crossing unit 600 includes a plurality of third hollow annular bodies 610 . Each of the third hollow annular bodies 610 includes a third annular body 611 and a third opening 612 . The third opening 612 penetrates the third annular body 611 . The third hollow rings 610 are disposed on the other side wall 13 of the base frame 10 at intervals. For example, the third annular bodies 611 are fixedly erected on the other side wall 13 of the base frame 10 . In addition, the third openings 612 do not have the same axis, and jointly define the oblique movement space 620 . In other words, the minimum linear distance 613 from the axis of each third opening 612 to the configuration plane of the infrastructure 10 (eg, the bottom surface 11 of the deep diving tank 14 ) gradually increases or decreases.

For example, the controller 800 activates the second laser generator 300 , the third laser generator 400 and the first laser generator 200 in sequence correspondingly, and when the diver D passes, the controller 800 correspondingly and sequentially Turn off the second laser generator 300 , the third laser generator 400 and the first laser generator 200 . However, the present creation is not limited to this order.

Fig. 3 is a schematic diagram of an underwater obstacle facility for diving training according to an embodiment of the present invention. As shown in FIG. 3 , on the basis of the above-mentioned embodiment, the underwater obstacle facility for diving training further includes an athletic field 700 . The arena 700 includes a plurality of (eg, 2) fourth laser generators 710 . The fourth laser generator 710 is fixed on the base frame 10 and is electrically connected to the controller 800 to project a three-dimensional pattern of the three-dimensional goal unit 720 through the control of the controller 800 . In this way, the diver D can compete against the goal channel 721 of the three-dimensional goal unit 720 in the deep diving tank 14 for shooting.

Exceptionally, Arena 700 can also become a diversified underwater venue. For example, for those who have watched the Harry Potter movies, the arena 700 can be a Quidditch match. By placing the underwater thruster K on the leg of the diver D, to simulate a wizard flying in the sky on a broom, Until the wizard shoots the ball into the three-dimensional goal unit 720, or until the snitch (eg, a small submarine) is caught.

In addition, the underwater obstacle facility further includes a plurality of sensors 900. The sensors 900 are located on the first to fourth laser generators 200, 300, 400, and 710, respectively, and are electrically connected to the controller 800 for sensing diving. Whether the person D contacts the above-mentioned laser light pattern to block the projection of the laser light pattern, so that the controller 800 can perform the subsequent response procedure.

It should be understood that the above-mentioned first to fourth laser generators 200 , 300 , 400 , and 710 include laser light-emitting diodes or other similar elements; as long as the desired three-dimensional pattern can be transmitted in the deep diving tank 14 , the above-mentioned third The first to fourth laser generators 200 , 300 , 400 , and 710 are not limited to their locations; the controller 800 is, for example, a control unit, a single chip, a software or firmware program, etc.; and the first hollow ring 110 , the second hollow ring Both the ring body 510 and the third hollow ring body 610 can be components made of, for example, plastic or other suitable materials.

Finally, the above disclosed embodiments are not intended to limit the present creation. Anyone who is familiar with this technique can make various changes and modifications without departing from the spirit and scope of the present creation, and they can be protected in this book. in creation. Therefore, the scope of protection of this creation should be determined by the scope of the appended patent application.

10: Infrastructure 11: Bottom surface 12, 13: Sidewalls 14: Deep diving tank 100: Horizontal crossing unit 110: The first hollow ring 111: The first torus 112: The first opening 113: Minimum straight-line distance 120: Linear motion space 121: Straight line direction 200: The first laser generator 210: Stereo Flip Unit 211: Horizontal column three-dimensional unit 212: Straight line direction 300: Second Laser Generator 310: Three-dimensional arc crossing group 311: Columnar three-dimensional unit 312: long axis direction 320: Through Space 330: Arc Movement Space 400: The third laser generator 410: Indicates rotary stereo unit 420: The third column-shaped three-dimensional pattern 421: Straight line direction 500: Lifting and crossing unit 510: Second hollow ring 511: Second Torus 512: Second Opening 520: Wave channel 521: Minimum straight-line distance 600: Oblique crossing unit 610: The third hollow ring 611: Third Torus 612: The third opening 613: Minimum straight-line distance 620: Oblique movement space 621: Straight line direction 700: Arena Stadium 710: Fourth Laser Generator 720: Stereo goal unit 721: Goal Channel 800: Controller 900: Sensor A1: The first spacing A2: Second spacing D: diver G: direction of gravity K: underwater thruster

In order to make the above-mentioned and other objects, features, advantages and embodiments of the present creation more obvious and easy to understand, the descriptions of the accompanying drawings are as follows: 1A and 1B are consecutive schematic diagrams of underwater obstacle facilities for diving training and competition purposes according to an embodiment of the present invention; Figures 2A and 2B are consecutive schematic diagrams of underwater obstacle facilities for diving training and competition purposes according to an embodiment of the present invention; and Figure 3 is a schematic diagram of an underwater obstacle facility for diving training and competition purposes according to an embodiment of the present invention.

10: Infrastructure

11: Bottom surface

12, 13: Sidewalls

14: Deep diving tank

100: Horizontal crossing unit

110: The first hollow ring

111: The first torus

112: The first opening

113: Minimum straight-line distance

120: Linear motion space

121: Straight line direction

200: The first laser generator

300: Second Laser Generator

310: Three-dimensional arc crossing group

311: Columnar three-dimensional unit

312: long axis direction

320: Through Space

330: Arc Movement Space

800: Controller

900: Sensor

D: diver

G: direction of gravity

Claims (10)

An underwater obstacle facility for diving training and competition, suitable for providing an infrastructure in confined waters, the underwater obstacle facility comprising: a horizontal traversing unit, fixed on a configuration plane of the basic structure, and having a linear motion space, wherein the linear direction of the linear motion space is perpendicular to a gravitational direction; A first laser generator is fixed on the base frame and is used for projecting a first laser light pattern in the base frame. The first laser light pattern simulates a three-dimensional flip unit. The three-dimensional flip unit is connected to the base structure. A side wall of the base structure maintains a first distance; A second laser generator is fixed on the base frame for projecting a second laser light pattern into the base frame, and the second laser light pattern simulates a three-dimensional arc with an arc-shaped movement space A type crossing group, the three-dimensional arc crossing group is between the horizontal crossing unit and the three-dimensional turning unit; and A controller is electrically connected to the first laser generator and the second laser generator for activating the first laser generator and the second laser generator. The underwater obstacle facility for diving training and competition as described in claim 1, wherein the three-dimensional arc traversing group further includes: A plurality of column-shaped three-dimensional units are formed at intervals on the configuration plane of the basic structure, and there is a passing space between any two adjacent column-shaped three-dimensional units, and the passing spaces together define the arc-shaped movement space . The underwater obstacle facility for diving training and competition as described in claim 1, wherein the three-dimensional turning unit further comprises: At least one horizontal column three-dimensional unit, the linear direction of the horizontal column three-dimensional unit and the gravity direction are perpendicular to each other. The underwater obstacle facilities for diving training and competition as described in claim 1, further include: A third laser generator is fixed on the base frame and is electrically connected to the controller for projecting a third laser light pattern into the base frame, and the third laser light pattern simulates an indicating rotating three-dimensional a unit, the indicating rotary three-dimensional unit is located on the disposition plane of the base frame, and maintains a second distance from the side wall of the base frame, Wherein, the direction of the straight line indicating the rotating solid unit and the direction of gravity are parallel to each other. The underwater obstacle facilities for diving training and competition as described in claim 1, further include: an arena, including at least a fourth laser generator, the fourth laser generator is fixed on the base frame, is electrically connected to the controller, and is used to project a fourth laser light pattern into the base frame , the fourth laser light pattern simulates at least one three-dimensional goal unit. The underwater obstacle facility for diving training and competition as described in claim 1, wherein the horizontal crossing unit further comprises: A plurality of first hollow rings are arranged at intervals on the disposition plane of the basic structure, wherein each of the first hollow rings has a first opening, and the first openings of the first hollow rings are mutually Alignment, so as to jointly define the linear motion space, and the minimum linear distances from each of the first openings to the disposition plane of the base structure are consistent. The underwater obstacle facilities for diving training and competition as described in claim 1, further include: A lift-through unit, fixed on the configuration plane on the basic structure, has a wave-shaped channel. The underwater obstacle facility for diving training and competition as described in claim 7, wherein the lifting and traversing unit further comprises: A plurality of second hollow rings are arranged at intervals on the disposition plane of the basic structure, wherein each of the second hollow rings has a second opening, and the second openings of the second hollow rings are mutually They do not have the same axis and jointly define the wave-shaped channel, and the minimum linear distances of the second openings to the configuration plane of the basic structure change periodically. The underwater obstacle facilities for diving training and competition as described in claim 1, further include: An oblique passing unit, fixed on the other side wall of the basic structure, has an oblique movement space, wherein the linear direction of the oblique movement space intersects with a gravity direction. The underwater obstacle facility for diving training and competition as claimed in claim 9, wherein the oblique crossing unit comprises a plurality of third hollow rings arranged at intervals, and each of the third hollow rings comprises a third hollow ring Openings, the third openings of the third hollow rings do not have the same axis, and jointly define the oblique movement space.

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