KR20080003905U - Horse riding simulation device - Google Patents

Abstract

The present invention relates to a horse riding apparatus.

Primarily, the base 10 and saddle 50 are included. On the other hand, the stacking device 30 is installed on the base 10 so as to be movable. The saddle 50 is also hypothesized in the loading device 30. The drive device 20 drives the loading device 30 and the saddle 50 to rotate along the elliptical trajectory so that the base 10 faces each other. The stacking device 30 can move stably along the elliptic stroke so as to face each other against the base 10. When the motor 23 is connected to the crank 13, the stacking device 30 is driven and rotated via the crank 13. The saddle 50 is adjustable to the loading device 30.

By doing so, a safe equestrian simulation apparatus is provided.

Base, Saddle, Loading Device, Motor, Drive Unit, Crank

Description

Equestrian simulation device {HORSE RIDING SIMULATION DEVICE}

1 is a three-dimensional display of the present invention.

Figure 2 is a local backsight three-dimensional view of the present invention.

Figure 3 is a side view of the present invention.

Figure 4 is another local backsight three-dimensional view of the present invention.

5, 6 and 7 are explanatory views showing the side operation of the present invention.

Figure 8 is a local exploded view of the present invention.

9 is another side view of the present invention.

10 is another local exploded view of the present invention;

Fig. 11 is an explanatory diagram showing the planar operation of the local part according to the present invention;

<Explanation of symbols for the main parts of the drawings>

10: Base

11: support pillar

12: support frame

13: crank

14, 17, 22, 61: pivot mounting shaft

15: Slide wheel

16: lever

20: drive unit

21: fly wheel

23, 55: motor

24: center of gravity

25, 27: connecting device

26: weight

30: loading device

31, 32: load

33: pipe

34: load frame

35: arc shape

36: distal end

37: top dead center

38: low

39: stopper

40: holding unit

41 body

42: non-circular storage room

50: birds

51: sliding rod

52: pad

53: adjustment rod

54, 63: fastening unit

56: screw

57: transverse beam

58: shaft bush

59: receptor

60: frame

62: elastic unit

64: head

65: support rod

66: adjustment hole

67: Stirrups of Horses

The present invention relates to a horse riding device that can move stably, like an elliptic equation.

Conventionally, all the known equestrian simulation apparatuses install a drive apparatus. When the birds are driven, they simulate the movement of various horses. Since the drive device is connected to the birds via the pivot mounting shaft, the birds are reciprocating momentarily and momentarily in opposite directions.

However, conventionally, the known equestrian simulation apparatus has not performed the shock absorbing operation in correspondence with the driving apparatus, and therefore always operates quite violently, causing injury to the user.

Accordingly, an object of the present invention is to provide a horse-bearing simulation device that can move stably, like an elliptic equation.

In order to achieve the objects, features, and the like employed in the present invention, the present invention will be described in detail with reference to the following specific embodiments.

According to the present invention, the equine simulation apparatus includes a support column 11. It extends upwards from the front portion of the base 10. The support frame 12 is installed at the rear surface portion of the base 10. The pair of cranks 13 are pivotally mounted and connected to the support frame 12 via the pivot mounting shaft 14. The slide wheel 15 is provided at the distal end of each crank 13. The drive device 20 includes a fly wheel 21 and pivotally installs and connects to the support frame 12 with the pivot mounting shaft 22. The shaft center 24 of the motor 23 is connected to the flywheel 21 by a connecting device 25 such as a gear or a chain or a belt. The weight 26 is also pivotally installed and connected to the pivot mounting shaft 14. Since it is connected to the pivot installation shaft 22 of the flywheel 21 via another connecting device 27, the weight 26, the flywheel 21 and the crank 13 are driven by a motor 23 Can rotate. Of course, you may connect directly to the motor 23, ie, the weight 26 and the flywheel 21 are unnecessary in the motor 23.

The stacking device 30 has at least one rod 31, 32. The front end is connected to the support column 11 of the base 10 via the pipe 33, the lever 16, and the pivot mounting shaft 17. At least one frame rod 34 is connected between the rods 31, 32. Each rod 31, 32 is installed on the slide wheel 15 of the crank 13 so that the arc-shaped end 35 is provided at the distal end 36 and can be moved. When driven by the crank 13, it can rotate as round or oval.

Since the intermediate arc end 35 has a top dead center 37 and a low point 38 (see FIGS. 5 to 7), the slide wheel 15 of the crank 13 is provided. Is moving to top dead center 37. The length of the rods 31 and 32 prevents the rods 31 and 32 from falling off and separating from the slide wheel 15 of the crank 13. Of course, the loading device 30 may add at least one stopper 39, and is connected to each arc-shaped end 35 or rods 31 and 32, and the slide wheel 15 is removed from the rods 31 and 32. Prevents falling off and separating. In addition, at least one holding unit 40 is disposed, and the slide wheel 15 is positioned by connecting to each arc-shaped end 35 or rods 31 and 32.

In operation, the motor 23 first drives the crank 23 and rotates the arc end 35 or end 36 of the rods 31 and 32 in a circular or ellipse. Since the arc end 35 or the distal end 36 of the rods 31 and 32 is not fixed to the arc end 35, the arc end 35 or the distal end 36 of the rods 31 and 32 is inertial. Corresponding to the slide wheel 15 of the crank 13, the shock absorbing movement is in progress.

The stacking device 30 has a body 41 and is installed on the rods 31 and 32 or the temporary rod 34. It has a non-circular accommodating chamber 42. The non-circular sliding rod 51 is installed in the non-circular accommodating chamber 42 of the body 41 and can move up and down movably, but cannot rotate. The pad 52 is installed on the sliding rod 51. The adjusting rod 53 is fitted into the sliding rod 51 and is fastened to the sliding rod 51 by the fastening attachment unit 54 (see FIG. 9). The motor 55 is installed in the rods 31 and 32 or the temporary rod 34. The screw 56 is connected to the motor 55 and screwed to the adjusting rod 53. Thus, the motor 55 drives the screw 56 and the adjusting rod 53 and adjusts the height of the saddle 50 and the pad 52. The saddle 50 has a transverse beam 57 and is arranged on the sliding rod 51. The shaft bush 58 and the two receptors 59 are mounted in the transverse beam 57. The frame 60 pivots and connects to the shaft bush 58 in the horizontal beam 57 via the pivot installation shaft 61. Therefore, in addition to supporting the pad 52, the frame 60 and the pad 52 can also be rotated so as to deviate from the beam 57 and the sliding rod 51 in the lateral direction.

Two elastic units 62 are provided between the frame 60, the transverse beam 57 and the sliding rod 51 for cushioning. The two fastening attachment units 63 pass through the horizontal beam 57, the receiver 59, and the elastic unit 62, and are screwed and connected to the frame 60. Since each has an enlarged head 64, it is possible to limit the rotation of the frame 60 so as to deviate from facing each other with the beam 57 or the sliding rod 51 in the lateral direction. The saddle 50 further includes a support rod 65, which is fastened to the frame 60. Since at least one adjustment hole 66 is provided, the stirrups 67 of two horses are hypothesized so that adjustment is possible.

In operation, reference will be made to FIGS. 5 to 7. The saddle 50 and the loading device 30 are driven by the driving of the motor 23, elliptical and reciprocally. In addition, the front end or the pipe 33 of the rods 31 and 32 may move back and forth or horizontally along the horizontal. If it is the arc-shaped end 35 or the distal end 36 of the loading device 30, it can rotate like circular or elliptical correspondence with the loading device 10. FIG. As a result, the loading device 30 and the saddle 50 can rotate like an ellipse in correspondence with the base 10.

According to the present invention, the object of the present invention, like an elliptic equation, can provide a horse riding simulation device that can be moved stably.

Claims (3)

In the equestrian simulation apparatus, it mainly comprises a base 10 and a saddle 50, the loading device 30 is hypothesized on the base 10 to be movable, and the saddle 50 is hypothesized on the loading device 30. , The driving device (20) drives the loading device (30) and the saddle (50), and corresponds to the base (10), horse riding simulation device, characterized in that rotating like an ellipse. The crank according to claim 1, wherein the base 10 has at least one crank 13, and the loading device 30 has at least one arc-shaped end 35 and is connected to the crank 13. Equestrian simulation device, characterized in that the operation (13). The drive device 20 according to claim 1, wherein the drive device 20 has at least one crank 13, is connected to the loading device 30, and further has one motor 23, and is connected to the crank 13. Equestrian simulation device, characterized in that.

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