Target training apparatus

Abstract

A target training apparatus includes an axle shaft, and the axle shaft includes three rebounding portions. Each one of the rebounding portions can be rotated relative to the axle shaft in order adjust angles among each one of the rebounding portions. In addition, each one of the rebounding portions can be positioned onto the axle shaft after the position thereof are set completely. The present invention utilizes three rebounding portions arranged at different angles as different ball striking targets, and the diversity of the ball bouncing direction is increased in order to improve the athlete training effect.

Claims

1. A target training apparatus, comprising: an axle shaft comprising a shaft member and two assembly disks arranged at two ends of the shaft member; the assembly disk is defined of a central location for connecting to the shaft member; a surrounding of the central location includes three pivotal attachment holes pivotally attached onto the three rebounding portions respectively one by one; three rebounding portions respectively connected to the axle shaft and capable of rotating relative to the axle shaft in order to adjust an angle among each one of the rebounding portions; each one of the rebounding portions configured to be positioned onto the axle shaft after positions thereof are set completely, wherein the assembly disk includes a plurality of positioning holes arranged corresponding to any one of the pivotal attachment holes and spaced apart from each other at an equal distance in order to allow each one of the rebounding portions to use an insertion pin for installing into one of the positioning holes for positioning thereof.

2. The target training apparatus according to claim 1, wherein each one of the rebounding portions is formed into a curved shape.

3. The target training apparatus according to claim 1, wherein each one of the rebounding portions includes a bracket in a curved shape; the bracket uses a plurality of springs to hook a net to be stretched into a curved surface.

Description

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

(1) FIG. 1 is a perspective view of the present invention;

(2) FIG. 2 is a perspective exploded view of the present invention;

(3) FIG. 3 is partial view showing a configuration of the rebounding portions and axle shaft of the present invention;

(4) FIG. 4 is a partial view showing a connecting member between the net and the bracket of the present invention;

(5) FIG. 5 is an illustration showing a state of use the present invention;

(6) FIG. 6 is a perspective view of the present invention after the positions of the rebounding portions are adjusted; and

(7) FIG. 7 is a perspective view of a prior art.

DETAILED DESCRIPTION OF THE INVENTION

(8) As shown in FIGS. 1 and 2, according to a target training apparatus of the present invention, the target training apparatus comprises three rebounding portions 1. Each one of the rebounding portions 1 includes a bracket 11, and the bracket 11 utilizes two lateral shafts 111 and a bottom shaft 112 connected to each other in order to formed into a U-shape structure. In addition, as shown in FIG. 4, a plurality of springs 12 are used to hook a net 13 in order to allow the net 13 to form into a stretched shape; wherein the two lateral shafts 111 are formed of curved shapes and are not in the same plane with the bottom shaft 112, such that the net 13 is stretched in a curved surface.

(9) The aforementioned three rebounding portions 1 are connected onto an axle shaft 2 respectively in order to allow the three nets 13 to be extended outward from the axle shaft 2. Each rebounding portion 1 can be rotated relative to the axle shaft 2 in order to allow adjust the relative position among each one of the rebounding portions 1, i.e. the angle among the rebounding portions 1, and can be further secured onto the axle shaft 2 after the position adjustment thereof. In this embodiment, the axle shaft 2 comprises a shaft member 21 and two assembly disks 22 arranged at two ends of the shaft member 21. As shown in FIGS. 2 and 3, the assembly disk 22 comprises two disk members 23 arranged parallel and spaced apart from each other. The two disk members 23 are correspondingly defined of a central location 231, three pivotal attachment holes 232 and eighteen positioning holes 233 respectively; wherein the three pivotal attachment holes 232 are circumferentially arranged at a surrounding of the central location 231. In addition, the three pivotal attachment holes 232 and the eighteen positioning holes 233 are divided into three hole groups 234. In other words, each set of the hole groups 234 includes a pivotal attachment hole 232 and six positioning holes 233. The six positioning holes 233 are respectively positioned at an equal distance away from the pivotal attachment hole 232.

(10) The aforementioned assembly disk 22 is connected to the shaft member 21 with the central location 231, and each one of the hole groups 234 is provided to connect to the rebounding portion; wherein the rebounding portion 1 is inserted between the two disk members 23 with its lateral shaft 111, and the lateral shaft 111 is pivotally attached onto the pivotal attachment hole 232 with a pivotal axle 14 in order to allow the rebounding portion to be rotated with the pivotal axle 14 as the center thereof. The lateral shaft 111 further includes an insertion hole 113; wherein a distance from the insertion hole 113 to the pivotal axle 14 is equivalent to a distance from the positioning hole 233 to the pivotal attachment hole 232. Accordingly, the rebounding portion can be configured at a desired position in order to allow the lateral shaft 111 to be pivotally rotated to the corresponding positioning hole 233. At this time, the insertion hole 113 overlaps with the positioning hole 233 such that an insertion pin 15 can be used to insert into the insertion hole 113 and the positioning hole 233 in order to secure the rebounding portion on the assembly disk 22.

(11) As shown in FIG. 5, in the present invention, two rebounding portions 1 can be used as a stand for supporting on the ground, and all of the three rebounding portions 1 can be used as the ball striking targets for athletes. In addition, the nets 13 can be utilized to bounce the ball 3 back. In addition, since the three rebounding portions face different directions, and the nets 13 are stretched in curved surfaces, the rebounding directions of the ball can be of greater diversity. As the rebounding directions are relatively hard to be predicted, the effect of athlete training can be achieved. In addition, the present invention further allows the adjustment of the relative positions of the three rebounding portions 1, i.e. the angles among the three rebounding portions 1. For example, as shown in FIG. 6, the two rebounding portions 1 used as the supporting stands can be opened at a relatively larger angle in order to lower the overall height of the apparatus. Moreover, the orientation of each rebounding portion 1 can be changed at the same time in order to change the rebounding direction to meet the demands for training.