KR101506904B1 - Apparatus for motion controler using rotational motion - Google Patents

Abstract

The present invention relates to a motion control remote controller using rotational motion, and includes a rotation handle coupled to one end of a rotation shaft passing through the interior of the housing to rotate the rotation axis. In addition, in the housing, the rotating shaft penetrates the central portion to be coupled with the rotating shaft, a plurality of irregularities are formed on the first circumferential surface of the rim, a locking rim is formed on the second circumferential surface of the rim, And a rotatable rotating body part. And an operation signal generation unit provided inside the housing and generating a different operation signal according to the rotation direction when the rotation unit rotates.

Description

APPARATUS FOR MOTION CONTROLLER USING ROTATIONAL MOTION [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a remote controller for motion control, and more particularly, to a motion control remote controller using a rotational motion to generate motion signals by a user's rotational motion to control motion.

Generally, a remote control is used to drive an object such as a toy having motion. Also, for the operation of a video game, the motion of a character of a video game and the like is controlled by using a remote controller such as a joystick. The remote controller for controlling the above-described motion uses a number key, a direction key, or a predetermined function key to generate an operation signal.

At present, the remote controller not only generates an operation signal for controlling the motion but also develops a means of conveying various feelings to the user. Among such remote controllers, a vibration generating device may be incorporated therein to allow the user to feel vibration when driving a game or an object. In addition, a remote controller that includes an audio output device on a remote control and outputs sound according to a user's operation is also provided.

Korean Registered Utility Model No. 20-0187095 entitled " Remote controller with a game machine " is a technology relating to a remote controller with a game machine equipped with a game machine capable of enjoying a game on one side of an integrated remote controller capable of remotely controlling an electronic product . The remote controller according to the related art has a liquid crystal screen in an integrated remote controller for controlling an electronic product remotely or setting conditions and the like, and displays setting, transmission / reception status, and the like of a model or code number of a corresponding electronic product through a liquid crystal screen . In addition, it is a remote controller with a game machine that improves the function of the integrated remote controller by allowing the user to enjoy the game through the liquid crystal screen.

The remote control according to the related art has an advantage that a remote control user can enjoy the game without having a separate game machine since the remote control has a game ratio. However, the operation (control) for enjoying the game is not much different from the conventional method. The user simply controls the game by pressing the direction key and the function key.

Therefore, the user has the disadvantage of feeling only visual pleasure through the liquid crystal screen while controlling the game using the remote control. Further, when a game is controlled for a long time using a conventional remote controller, fatigue is accumulated on a specific body part due to a fixed posture. Further, when the user is a child, it is difficult to control the motion by using the direction key and the operation key in controlling the game, the toys, etc. by using the conventional button-type remote control.

The present invention provides a motion control remote controller using rotational motion according to the present invention.

First, for the purpose of providing a remote control capable of controlling an object or a motion of a character, such as a video game, a playground, a toy, or an electronic device, by generating an operation signal by a rotational motion instead of a button operation of the remote controller do.

Second, the object of the present invention is to provide a remote controller that allows the user to feel the pleasure of the user directly through the motion control as well as the visual pleasure when the motion of the character or the object is controlled.

Third, the object of the present invention is to provide a remote control capable of minimizing the fatigue accumulation of a specific body part caused by repeated button operation in motion control.

Fourth, the object of the present invention is to provide a remote controller that facilitates motion control of a video game or a motion toy even if the user is a child.

The solution of the present invention is not limited to those mentioned above, and other solutions not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided a motion control remote controller using rotary motion according to the present invention includes a rotary knob coupled to one end of a rotary shaft passing through the interior of a housing to rotate the rotary shaft.

Further, in the housing, the rotating shaft passes through the central portion and is coupled to the rotating shaft, a plurality of irregularities are formed on the first circumferential surface of the rim, a locking rim is formed on the second circumferential surface of the rim, And a rotating body portion that rotates in accordance with the rotational motion.

And an operation signal generation unit provided inside the housing and generating a different operation signal according to the rotation direction when the rotation unit rotates.

The irregularities formed on the first circumferential surface of the rim of the rotator are spaced apart from each other in the transverse or oblique direction, and the second circumferential surface of the rim of the rotator includes a jaw in one section.

The rotating body is formed in a disk shape and rotates together with the rotating shaft in accordance with the rotation of the rotating handle.

The operation signal generating unit may include a first signal generating member that generates an operation signal upon entering and exiting the unevenness of the rotating body unit and generates a different operation signal in accordance with the entering direction of the recessed and recessed portions along the rotating direction of the rotating body unit . And a second signal generating member for causing an operation signal to be generated in a direction of a rotational force applied to the rotary body portion in contact with the engagement jaw at the time of rotation of the rotary body portion and for generating a different operation signal in accordance with the contact direction of the engagement jaw .

Here, the first signal generating member switches signals so that when the rotating body rotates in one direction, the first signal generating member enters the unevenness in the other direction to generate one directional operation signal corresponding to the rotating direction of the rotating body unit .

The second signal generating member switches the signal so that one directional operation signal is continuously generated according to the rotational force in one direction applied to the latching jaw when the latching jaw rotates in one direction and the rotational force is transmitted by the contact. . And the second signal generating member is switched so that the intensity of the operation signal is maintained while the engaging step is touched in one direction.

The operation signal generation unit further includes a control unit for determining the type of operation signal according to the operation of the first signal generation member and the second signal generation member, and generating an operation signal according to the determined type.

The rotation restoring member is installed inside the housing and rotates the rotator in the other direction by the number of rotations when the rotator is rotated in one direction.

The apparatus further includes a transmitter for transmitting the operation signal generated by the operation signal generator to the RF signal communication system, the infrared communication system, the NFC communication system, or the RFID communication system.

The apparatus further includes a sensor signal generator for generating and transmitting an operation signal corresponding to a motion direction sensed by the triaxial gyro sensor.

The motion control remote controller using the rotary motion according to the present invention has the following effects.

First, by rotating the rotary body through the rotary knob and generating an operation signal by the operation signal generating unit in accordance with the rotary motion of the rotary unit, the operation signal corresponding to the rotating direction and the direction in which the rotational force is applied, You can control the motion of an object or character, such as a device.

Second, the motion signal is generated by the user's rotational motion, not the control by the button operation, and the motion of the object or the character is controlled, so that the user can directly feel the motion and control the motion.

Third, the user can perform rotational motion and various motions to control motion, thereby minimizing fatigue accumulation of a specific body part in long-time motion control.

Fourth, remote control operation for motion control is enabled only by rotational motion, so that motion control of a video game or motion toy can be facilitated even if the user is a child.

The effects of the present invention are not limited to those mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the following description.

1 is a view for explaining a motion control remote controller using a rotational motion according to the present invention.
FIG. 2 and FIG. 3 are other views for explaining a motion control remote controller using rotational motion according to the present invention.
FIG. 4 is a view for explaining a motion control remote controller using rotational motion according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in detail with reference to the accompanying drawings. 1 is a view for explaining a motion control remote controller using a rotational motion according to the present invention. The motion control remote controller 100 using the rotary motion includes a rotary knob 120 coupled to one end of a rotary shaft 111 passing through the inside of the housing 110 to rotate the rotary shaft 111 do.

The rotating shaft 111 penetrates through the center of the housing 110 and is coupled to the rotating shaft 111. A plurality of protrusions 131 are formed on the first circumferential surface of the rim and a plurality of protrusions 131 are formed on the second circumferential surface of the rim And a rotatable body 130 which forms the engaging jaw 132 and rotates in accordance with the rotation of the rotary knob 120.

In addition, when the rotating body 130 is rotated, a different operating signal is generated in the housing 110 and a different operating signal is generated depending on the direction of the force applied to the rotating body 130 And an operation signal generating unit 140.

In one embodiment, the housing 110 is separable and engageable and can be formed in a variety of shapes such as transparent, opaque, or translucent. In addition, a space is formed in the housing 110, and a rotating body 130, an operation signal generating unit 140, and a rotating shaft 111 are installed and arranged. The housing 110 is engaged with the rotating shaft 111. The rotating shaft 111 passes through one side and the other side of the housing 110 and is coupled with the housing 110. In addition, the housing 110 may be made of plastic, acrylic, or the like, and may be made of synthetic resin.

The rotary knob 120 is fitted into the one end of the rotary shaft through which the housing 110 is coupled. The rotary knob 120 is disposed on the outer side of the housing 110 in combination with the end of the rotary shaft 111 protruding out of the housing 110. The rotary knob 120 may be implemented in various forms so that the user can perform rotational motion after gripping.

The user rotates the rotary knob 120 after grasping the rotary knob 120 and the rotary force at this time will be transmitted to the rotary shaft 111 and the rotary body 130. [ The size and shape of the rotary knob 120 are not limited to any one. The rotational motion of the user through the rotary knob 120 is transmitted to both the rotary shaft 111 and the rotary body 130 and generates an operation signal by using the rotary motion transmitted.

In one embodiment, the rotating body part 130 is disposed inside the housing 110 and is coupled to the rotating shaft 111 in such a manner that the central part passes through the rotating shaft 111. Therefore, when the rotary knob 120 rotates, the rotary body 130 also rotates together. The rotary body part 130 is formed in a disk shape and has serrated irregularities along the first circumferential surface of the rim. Accordingly, the rotating body portion 130 having the first circumferential surface corresponds to the toothed wheel.

The concave portion direction of the concavo-convex formed on the first circumferential surface of the rim portion of the rotary body portion 130 is parallel or oblique to the rotation axis, and the respective concave portions are spaced apart from each other. The transverse direction according to the present invention means a transverse direction orthogonal to the rotational direction of the rotator when the rotational direction of the rotator is taken as the longitudinal direction, as shown in Fig. Further, the irregularities according to the present invention are not only arranged in the transverse direction but also in the oblique direction It is possible. This is because the first signal generating member can be regularly entered into each recess.

Here, the first circumferential surface and the second circumferential surface are formed by a single rim. The first circumferential surface refers to a rim with ridges in the rim. The second circumferential surface means a rim with a protrusion 132 formed in one section without forming protrusions and recesses. From the viewpoint of the bottom surface excluding the unevenness, the bottom height of the first circumferential surface is formed to be lower than the bottom height of the second circumferential surface (see FIG. 1). On the other hand, it is also possible to change the left and right arrangement of the first circumferential surface and the second circumferential surface.

The rotary body part 130 and the operation signal generation part 140 of the motion control remote controller 100 using the rotary motion according to the present invention can be described with reference to FIG. 2 and FIG. 2 and 3 are diagrams for explaining a principle of generating an operation signal through the rotary body part 130 and the operation signal generation part 140 and include a partial enlarged view of the rotary body part 130 and the operation signal generation part 140 .

As shown in FIGS. 2 and 3, the first circumferential surface of the rim forms a concavity and convexity 131, and the second circumferential surface of the rim has a concavo-convex 131, And a latching jaw 132 at one end of the second circumferential edge of the rim. The rotary body part 130 is formed in a disk shape and rotates together with the rotary shaft 111 in accordance with the rotation of the rotary knob part 120.

The rotary body part 130 is formed in a first circumferential surface of the rim with irregularities having the same shape as a toothed wheel, and the second circumferential surface is in the shape of a disk made of a surface other than a toothed wheel. Here, the latching jaw 132 is disposed in one section of the peripheral second circumferential edge of the portion where the concavities and convexities 131 are not formed. The engaging jaw 132 may or may not have the shape of a tooth-like concavity and convexity.

The shape of the rotator 130 can be realized not only in the shape of a disk but also in various shapes. The size may be variously implemented. The position where the rotating body 130 is coupled to the rotating shaft 111 is not limited. However, in the present invention, the rotating body 130 is positioned inside the housing 110 so as to be close to the rotating handle 120.

2 and 3, the operation signal generating unit 140 is coupled to the housing 110 so as to be disposed at an upper portion of the rotator unit 130. As shown in FIG. 2 and 3 do not show the housing 110 disposed below for a specific explanation of the present invention.

The operation signal generating unit 140 generates an operation signal when the door 130 is moved in and out of the concave and convex portions 131 of the rotary body 130 and moves the concave and convexes 131 in the direction And a first signal generating member 141 for causing a different operation signal to be generated.

The rotation of the rotary body part 130 causes the rotary body part 130 to be brought into contact with the engagement step 132 so that an operation signal is generated in the rotation direction of the rotary body part 130 coupled with the engagement step 132, And a second signal generating member 142 for generating a different operation signal according to the direction.

The first signal generating member 141 and the second signal generating member 142 of the operation signal generating unit 140 are formed in the shape of a rod in the present invention, but they are not limited to a specific shape. The first signal generating member 141 according to the present invention is bent and extended so as to be able to enter and exit the unevenness 131 formed in the rotating body part 130. [ Therefore, when the rotary body part 130 rotates, the end of the first signal generating member 141 enters the recessed part of the concavity and convexity 131.

The first signal generating member 141 generates an operation signal in one direction corresponding to the rotation direction of the rotator 130 when the rotator 130 rotates in one direction, . If the rotary member 130 rotates in the clockwise direction, the first signal generating member 141 will enter the concavities 131 in the counterclockwise direction. This is because the rotary body 130 is formed in the form of a toothed wheel.

In other words, when the rotating body portion 130 rotates clockwise, the first signal generating member 141 is pushed clockwise, and after the constant section is pushed, the first signal generating member 141 is rotated counterclockwise in the counter- 131). The above description will be similarly applied when the rotating body portion 130 rotates counterclockwise. However, the directions will differ from each other. This can be confirmed through a partially enlarged view of FIG.

The second signal generating member 142 is rotated by the second signal generating member 142 so that one directional operation signal is generated according to the rotational force applied to the latching jaw 132 when the latching jaw 132 rotates in one direction, As shown in FIG. As shown in FIG. 2, the second signal generating member 142 switches the electrical signal by the latching jaw 132.

The second signal generating member 142 will keep the electrical signal continuously on for generation of the operation signal while the rotational force is applied in one direction by the engagement jaw 132. [ The second signal generating member 142 is switched so that the strength of the operation signal is maintained while the latching jaw 132 is contacted in one direction.

In the present invention, 'contact' means a state in which the stopping jaw 132 and the second signal generating member 142 are in contact with each other. In addition, in the present invention, the signal is switched to the ON state by the second signal generating member 142 assuming that the rotational force is continuously transmitted by the user.

 In the present invention, switching means ON / OFF operation of an electric signal, and electricity at this time can be supplied by a battery type power supply (not shown) included in the housing 110 . In the present invention, the power source unit may be included in the housing 110, and may not be included in the housing 110, but may be supplied with power from an external power source unit.

FIG. 4 is a view for explaining a motion control remote controller using rotational motion according to the present invention. 4, the motion signal generating unit 140 of the motion control remote controller 100 using the rotational motion generates the motion signal generating unit 140 using the first signal generating member 141 and the second signal generating member And a controller 143 for determining the type of the operation signal according to the operation of the controller 142 and generating an operation signal according to the determined type.

The control unit 143 may be implemented in the form of an IC circuit and may generate different types of operation signals 141 and 142 according to the switching caused by the operation of the first signal generating member 141 and the second signal generating member 142. [ Lt; / RTI >

For example, the switching signal generated by the counterclockwise movement of the first signal generating member 141 may be determined to be an operation signal for the linear operation, thereby generating an operation signal corresponding thereto. Also. The switching signal generated by the clockwise movement of the first signal generating member 141 may be determined as the operation signal for the backward operation and accordingly the operation signal may be generated. The type of the above-mentioned operation signal may be variously changed, and may be set in advance.

In other words, the control unit 143 may determine the operation signal for the linear motion or the backward movement and generate the operation signal, in accordance with the direction in which the user rotates the rotary knob 120.

The motion control remote controller 100 using the rotary motion according to the present invention includes a transmitter 130 for transmitting an operation signal generated by the operation signal generator 140 to one of an RF signal communication system, an infrared communication system, an NFC communication system, (150). The transmission unit 150 transmits the operation signal generated by the operation signal generation unit 140 to a toy, a video game, an electronic device, or the like.

The present invention is not limited to this, and the transmission unit 140 may be connected to a toy, a video game, or an electronic device by wire to send an operation signal. The controller 143 may be installed inside the housing 110 or may receive a switching signal generated by the operation signal generator 140 included in a toy, a video game, an electronic device, or the like.

Further, the motion control remote controller 100 using the rotary motion according to the present invention may further include a sensor signal generation unit 160 for generating and transmitting an operation signal corresponding to the motion direction sensed by the 3-axis gyro sensor There will be.

The user may generate an operation signal even if the user does not rotate the rotary knob 120 by the sensor signal generating unit 160. [ The sensor signal generating unit 160 may detect movement of a user by a three-axis gyroscope such as a gyroscope sensor, generate various types of operation signals according to the sensed signals, and transmit the generated signals to the transmitter 150 will be. The sensor signal generator 160 may be installed inside the housing 110 and may generate a complex operation signal together with the operation signal generator 140.

In addition, the motion control remote controller 100 using the rotary motion according to the present invention is installed inside the housing 110, and when the rotary body 130 rotates in one direction, the rotary body 130 is rotated a number of times And a rotation restoring member (not shown) that rotates in the other direction.

The motion control remote controller 100 using the rotary motion may rotate the rotary knob 120 in a direction opposite to the rotation of the rotary knob 120 including the rotation restoration member. Therefore, when the user enjoys the fishing game with the motion control remote controller 100 using the rotary motion, the motion control remote controller 100 using the rotary motion can play the same role as the fishing rod. At this time, the rotary knob 120 plays the same role as the reel of the fishing rod, so that it is possible to provide the feeling that is felt when the user enjoys the actual fishing, in addition to the pleasure of controlling the motion to the user.

When the rotation restoration member is operated, the operation signal generation unit 140 may be controlled by the control unit 143 so as not to generate the operation signal. On the other hand, even when the rotation restoring member is operated, the operation signal generating unit 140 may be controlled by the control unit 143 so as to generate an operation signal.

The motion control remote controller 100 using the rotary motion according to the present invention described with reference to FIGS. 1 to 4 rotates the rotary body part 130 through the rotary knob 120 and rotates the rotary body part 130 The signal generating unit 140 generates an operation signal so that motion of an object such as a video game, a toy, or an electronic device can be controlled by using an operation signal corresponding to a direction in which the rotational direction and the rotational force are applied.

In addition, it is possible to control the motion by controlling the motion of the object or the character by directly generating the motion signal by the rotation motion by the user rather than the control by the button operation.

In addition, by taking a rotational motion and various motions for the user to control the motion, fatigue accumulation of a specific body part can be minimized during long-time motion control.

Further, the remote control operation for motion control can be performed only by the rotary motion, so that the motion control of the video game or the motion toy can be facilitated even when the user is a child.

It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. It will be understood that variations and specific embodiments which may occur to those skilled in the art are included within the scope of the present invention.

100: Motion control remote control using rotary motion
110: housing 111:
120: rotary knob 130: rotary body
131: concave 132:
140: operation signal generation unit 141: first signal generation member
142: second signal generating member 143:
150: transmitting unit 160: sensor signal generating unit

Claims (11)

A rotating handle coupled to one end of a rotating shaft passing through the inside of the housing to rotate the rotating shaft;
A plurality of protrusions and recesses are formed on a first circumferential surface of the rim and a locking protrusion is formed on a second circumferential surface of the rim, A rotating body rotating in accordance with the rotation; And
An operation signal generating unit which is installed inside the housing and generates a different operation signal in accordance with the rotation direction when the rotating body rotates,
Motion control remote control using rotary motion. The method according to claim 1,
The concave portion direction of the concavo-convex formed on the first circumferential surface of the rim in the rotary body portion is parallel or oblique to the rotation axis, the respective concave portions are disposed apart from each other,
And a second circumferential surface of the rim of the rotator is provided with a latching jaw in one section. 3. The method of claim 2,
Wherein the rotary body is formed in a disk shape and the rotary body rotates together with the rotary shaft in accordance with the rotation of the rotary knob. The method according to claim 1,
The operation signal generation unit
A first signal generating member for generating an operation signal upon entering and exiting the concave and convex portions of the rotating body portion and for generating different operation signals in accordance with the entering direction of the concave and convex portions along the rotational direction of the rotating body portion; And
A second signal generating member which is brought into contact with the engaging jaw at the time of rotation of the rotator and which generates an operation signal in the rotating direction of the rotating body coupled with the engaging jaw and generates a different operation signal in accordance with the contact direction of the engaging jaw,
And a control unit for controlling the operation of the remote controller. 5. The method of claim 4,
The first signal generating member switches signals so that when the rotating body rotates in one direction, the first signal generating member enters the unevenness in the other direction to generate one directional operation signal corresponding to the rotating direction of the rotating body unit Motion control remote control using rotary motion. 5. The method of claim 4,
The second signal generating member may be configured to switch the signal so that one directional operation signal is continuously generated in accordance with the rotational force applied to the latching jaw when the latching jaw rotates in one direction and the rotational force is transmitted by the contact Features a motion control remote control with rotary motion. The method according to claim 6,
And the second signal generating member is switched so that the intensity of the operation signal is maintained while the first signal generating member is in contact with the latching jaw in one direction. 5. The method of claim 4,
Wherein the motion signal generation unit further comprises a control unit for determining a type of an operation signal according to an operation of the first signal generation member and the second signal generation member and generating an operation signal according to the determined type, Control remote control. The method of claim 3,
Further comprising a rotation restoring member provided inside the housing and configured to rotate the rotating body in the other direction by the number of rotations when the rotating body rotates in one direction. The method of claim 3,
Further comprising a transmitter for transmitting the operation signal generated by the operation signal generator through any one of an RF signal communication system, an infrared communication system, an NFC communication system, and an RFID communication system, remote. 11. The method of claim 10,
Further comprising a sensor signal generator for generating and transmitting an operation signal corresponding to a motion direction sensed by the triaxial gyro sensor.

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