KR102632633B1 - Sonic vibration cushion - Google Patents

Abstract

The present invention discloses a cushion that can induce sound wave vibrations to acoustic sources while maintaining the original function of the cushion.
The sonic vibration cushion according to the present invention includes a sonic vibration module for inducing vibration in response to an acoustic signal, a main body for accommodating the sonic vibration module, and is installed inside the main body to convert the acoustic signal into a driving signal of the sonic vibration module. It consists of a charging unit that converts, receives external power and charges the battery, and a vibration transmission arm that is hinged at least two times on the outer circumference of the main body to transmit the rear vibration energy of the sound wave vibration module to the front. The transmission arm is made of a metal material, has a structure bent in the shape of an arc, has a certain elasticity, and has a structure that folds outward with a certain elasticity when the user's body load is pressed, and has a hinge provided on the outer peripheral surface of the main body. It is characterized by being rotated at a certain angle through.
Therefore, the present invention has the effect of enabling the operation of a sonic vibrator installed into the cushion while maintaining the original function of the cushion, and further, fastening at least two or more elastic frames on the outer peripheral surface of the sonic vibrator installed inside the cushion, and By inducing close contact between the sonic vibrator and the body when pressed, the sonic vibration effect can be increased.

Description

Sonic vibration cushion {SONIC VIBRATION CUSHION}

The present invention relates to sonic vibration, and more specifically, to provide a sonic vibration device inside the cushion, and to construct an elastic frame to suppress the offsetting force of the physical vibration of the sonic vibration device to generate physical vibration corresponding to the acoustic signal. It is about an inducible sonic vibration cushion.

In general, people suffer from various diseases such as muscle stiffness, chronic fatigue, and muscle cramps due to various stresses in everyday life. Recently, the number of people receiving massages has been increasing to relieve muscle stiffness and nerve fatigue. Conventional massage was performed by a person directly applying pressure to a part of the body using hands or tools.

As the population receiving massages gradually increases, various massage machines that can perform massages using machines rather than people are being developed. Examples of massage machines may include massage chairs, calf massagers, foot massagers, etc. These massage machines generally use a vibration method using a motor or actuator. Recently, mats have been developed to enable heat and vibration induction by providing a vibration device inside the heating mat.

As in the attached registered patent, the sonic vibration heating mat includes at least one heat transfer plate and at least one sonic vibrator, where the heat transfer plate generates heat and the sonic vibrator generates vibration. Here, the sonic vibration thermal mat generates vibration using a sonic vibrator rather than vibration caused by a motor. A sound wave vibrator generates vibration by applying current to a voice coil located within the magnetic field of a permanent magnet and converting it into sound wave vibration caused by the up and down movement of the permanent magnet. The vibration generated by the sonic vibrator is transmitted to the user lying on the sonic vibration thermal mat, relaxing the user's mind and body.

That is, as shown in Figure 1, the sonic vibration thermal mat 1 includes a cover 11, at least one heat transfer plate 12, a temperature sensor 13, a cushion panel 14, at least one sonic vibrator 20, and Includes control box (15). The cover 11 is a rectangular case with an open bottom, and a heat transfer plate 12, a temperature sensor 13, a cushion panel 14, at least one sonic vibrator 20, and a control box 15 are disposed inside. . The upper surface of the cover 11, which is in contact with the user's body, may be made of artificial leather, natural leather, etc.

The heat transfer plate 12 is formed in the shape of a square plate that generates heat. The heat transfer plate 12 includes a square plate and a heating wire built into the square plate. A heating wire is a wire that generates heat. Generally, the heat transfer plate 12 is made of a metal with high thermal conductivity in order to effectively transfer heat generated from the heating wire. The temperature sensor 13 is disposed below the heat transfer plate 12 and detects the temperature of the heat transfer plate 12.

The cushion panel 14 supports the user's body. At least one sonic vibrator 20 is built into the cushion panel 14. The cushion panel 14 includes an upper cushion panel 141 disposed between the heat transfer plate 12 and the sound wave vibrator 20 and a lower cushion panel 142 surrounding the sound wave vibrator 20. The upper cushion panel 141 is formed in a rectangular flat shape and is located below the heat transfer plate 12. The lower cushion panel 142 has at least one insertion groove in the center into which at least one sonic vibrator 20 is inserted and is formed in a rectangular flat shape. The lower cushion panel 142 is located below the upper cushion panel 141. The lower cushion panel 142 fixes the sonic vibrator 20 inserted into the insertion groove () in the center. The upper cushion panel 141 and the lower cushion panel 142 are manufactured from materials such as urethane foam and expanded polypropylene (EPP).

However, the conventional cushion panel equipped with a plurality of sound wave vibrators is supported on the ground due to the nature of the mat, so the vibration force of the sound wave vibrator can be transmitted to the body, but in a general cushion structure without a panel, it is usually Because it is used in a vertical position, a problem occurs where the vibration force of the sonic vibrator is canceled out inside the cushion. That is, as in the prior art, it is impossible to install a sonic vibrator in a normal cushion that does not have a cushion panel with a certain strength, or a panel with a certain strength or more must be installed behind the cushion for the sonic vibration to be transmitted to the body. It is inevitable that the original function of the cushion will be lost.

Republic of Korea Patent No. 10-2179265, registration date: November 10, 2020, title of invention ‘Sonic vibration heating mat using sonic actuator’

The present invention was created to solve this problem, and the purpose of the present invention is to provide a sonic vibration cushion that allows operation of a sonic vibrator built into the cushion while maintaining the original function of the cushion.

Another object of the present invention is to provide a sonic vibration cushion that can increase the sonic vibration effect by fastening at least two elastic frames on the outer peripheral surface of the sonic vibrator installed inside the cushion and inducing close contact between the sonic vibrator and the body when the body is pressed. In providing.

In the sonic vibration cushion according to the present invention for achieving the above object, a sonic vibrator is installed inside the cushion of a predetermined shape, and a cushion material is filled between the sonic vibrator and the cushion, wherein the sonic vibrator transmits a sound signal. A sonic vibration module for inducing vibration in response, a main body for accommodating the sonic vibration module, and installed inside the main body to convert an acoustic signal into a driving signal of the sonic vibration module and receive external power. It is characterized in that it consists of a charging unit that performs charging of the battery, and at least two vibration transmission arms that are hinged on the outer peripheral surface of the main body to transmit the rear vibration energy of the sound wave vibration module to the front.
Meanwhile, the vibration transmission arm according to the present invention is made of a metal material, has a structure bent in an arc shape, has a certain elasticity, and has a structure that has a certain elasticity and folds outward when the user's body load is pressed. , characterized in that it is rotated at a certain angle through a hinge provided on the outer peripheral surface of the main body.

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In addition, a silicon ring for elastically fixing the sonic vibration module and the main body to each other; Rotating rods for rotating each vibration transmission arm provided on the outer peripheral surface of the main body at a predetermined angle; Each of the vibration transmission arms includes a rotating sphere for accommodating the rotating rod; It is characterized in that it includes an installation tool for installing the vibration transmission arm on the outer peripheral surface of the main body.

In addition, the sound wave vibration module is a means for experiencing sound signals, includes a haptic function, and is characterized in that sound wave vibration is achieved by a sense signal intentionally created in sound or video.

In addition, the sensory signal is characterized as a signal for inducing a bodily sensation corresponding to situational changes and emotional changes provided on the metaverse.

In addition, the main body includes a charging unit for receiving external power wired or wirelessly and charging the battery; A main board that receives sound signals and sound wave vibration signals corresponding to the sound signals based on short-distance communication with the user's mobile; an amplification board that outputs the sound signal and the sound wave vibration signal provided from the main board at a set gain; a speaker driver that drives the speaker in response to the sound signal; and a sonic vibration driver that provides the sonic vibration signal to the sonic vibrator.

The sonic vibration cushion presented in the present invention has the effect of enabling the operation of a sonic vibrator installed inside the cushion while maintaining the original function of the cushion, and also has at least two or more elastic frames on the outer circumferential surface of the sonic vibrator installed inside the cushion. By fastening and inducing close contact between the sonic vibrator and the body when the body is pressed, the sonic vibration effect can be increased.

Figure 1 is a configuration diagram for explaining a mat equipped with a conventional sonic vibrator.
Figure 2 is a perspective view for explaining the sonic vibration cushion according to the present invention.
Figure 3 is a configuration diagram to explain the main functions of the sonic vibrator 210 presented in the present invention.
Figure 4 is an exploded perspective view showing the sonic vibrator 210 according to the present invention.
Figure 5 is a configuration diagram to explain the main functions of the main body according to the present invention.

Hereinafter, a preferred embodiment of the present invention will be described in detail based on the attached illustration drawings.

Figure 2 is a perspective view for explaining the sonic vibration cushion according to the present invention. As shown, a sonic vibrator 210 is installed inside a cushion 200 of a predetermined shape, and a cushion material is filled between the sonic vibrator 210 and the cushion 200. The cushioning material may include waste fiber, plastic cushioning material, sponge cushioning material, microfiber, etc. In the present invention, after installing the sonic vibrator 210 inside the cushion 200, the sonic vibration generated by the sonic vibrator 210 is transmitted to the user's body. In addition, in order to maintain the original function of the cushion 200, no separate installation other than the cushion material is maintained between the sonic vibrator 210 and the cushion 200.

Therefore, when the cushion 200 is used as a backrest, sound wave vibration corresponding to the sound signal set through the sound wave vibrator 210 is transmitted to the user's body. The sound wave vibrator 210 is for transmitting vibration waves corresponding to sound signals to the user's body. During the sound wave vibration process, the vibration direction of the sound wave vibrator 210 is such that the vibration energy flows forward and backward in the vertical direction of the sound wave vibrator 210. It is delivered. Therefore, when the sound wave vibration energy of the sound wave vibrator 210 is transmitted forward and backward, a mutual cancellation phenomenon occurs, so that the sound wave vibration radiated forward is inevitably weak. To prevent this, when a plate with a certain strength is installed behind the sonic vibrator 210, the original function of the cushion 200 is lost. Accordingly, as a structure for transmitting the vibration energy transmitted to the rear of the sound wave vibrator 210 to the front of the sound wave vibrator 210, that is, to the user's body, at least two vibration transmission arms are installed on the outer peripheral surface of the sound wave vibrator 210. It is provided so that the vibration wave transmitted to the rear of the sound wave vibrator 210 is transmitted to the user's body, that is, to the front.

Figure 3 is a configuration diagram to explain the main functions of the sonic vibrator 210 presented in the present invention. As shown, the sound wave vibrator 210 includes a sound wave vibration module 211 for inducing vibration in response to the sound signal, and a sound wave vibration module 211 inside the main body 221 for accommodating the sound wave vibration module 211. A charging unit that converts a driving signal of the sonic vibration module 211 and charges the battery by receiving external power, and is hinged at least two times on the outer circumferential surface of the main body of the sonic vibration module 211. It consists of a vibration transmission arm 223 for transmitting rear vibration energy to the front.

The vibration transmission arm 223 is made of a metal material, has a structure bent in an arc shape, and has a certain amount of elasticity. The vibration transmission arm 223 has a structure that has a certain elasticity and folds outward when the user's body load is pressed, and is rotated at a certain angle through a hinge provided on the outer peripheral surface of the main body 221. Therefore, when the body load is pressed at the end of the vibration transfer arm 223, the other end of the vibration transfer arm 223 presses the back of the sound wave vibration module 211. This is to allow the sound wave vibration module 211 to transmit rear sound wave vibration to the user's body through the vibration transmission arm 223. Of course, the front of the sonic vibration module 211 transmits sonic vibration to the user's body.

Therefore, by transmitting the sonic vibration vibrating at the front and rear of the sonic vibration module 211 to the user's body, the offset phenomenon of the sonic vibration is minimized to increase the user's perceived enjoyment or to reduce the power consumption of the sonic vibration module. can be minimized.

Meanwhile, as shown, one end of the main body 221 includes an output terminal 215 that outputs a driving signal corresponding to the power and sound signals to the sonic vibration module 211, and the sonic vibration module 211 ) is provided at one end of the input terminal 213 for receiving a driving signal provided from the output terminal 215. After fastening the sonic vibration module 211 to the inside of the main body 221, signal connection is made to each other through the output terminal 215 and the input terminal 213.

In addition, the present invention describes the sound wave vibration module 211 for inducing sound wave vibration through the cushion 200, but if necessary, a speaker for outputting a sound signal to one side of the cushion 200 can be installed. You can. At this time, the output terminal 215 provided at one end of the main body 221 further includes an output terminal for driving the speaker in addition to driving the sound wave vibration module 211.

The sound wave vibration module 211 is simply used as a means to experience sound signals, but may be used in a haptic concept. This will be able to provide a tangible signal intentionally created in video rather than sound. For example, in the metaverse, urgent situations can be provided through vibration, or sudden emotional changes can be provided through vibration. This will allow physical contact and psychological changes between the virtual space and characters created on the metaverse to be transmitted through the sound wave vibration module 211.

In addition, the sound wave vibrator 210 presented in the present invention may require wireless connection with a mobile device in order to transmit external acoustic signals and external haptic signals through vibration. It is equipped with short-range communication modules such as Bluetooth and ZigBee, and vibrates the user's body to respond to sound and video signals provided through listening to sound, watching movies, using the metaverse, etc. based on wireless connection with the user's mobile phone. It is to induce.

Figure 4 is an exploded perspective view showing the sonic vibrator 210 according to the present invention. As shown, a silicon ring 229 for elastically fixing the sonic vibration module 211 and the main body 221 to each other, and each vibration transmission arm 223 provided on the outer peripheral surface of the main body 221. ) includes each rotating rod 225 for rotating the rotating rod 225 at a predetermined angle, and each vibration transmission arm 223 includes a rotating sphere 227 for accommodating the rotating rod 225, and the main body 221. An installation hole 231 for installing the vibration transmission arm 223 is provided on the outer peripheral surface.

The silicone ring 229 prevents the sound wave vibration module 211 and the main body 221 from separating and provides elasticity during the mutual fastening process. This prevents the vibration force from being transmitted to the main body 221 itself due to lateral vibration as the vibration force of the sound wave vibration module 211 is transmitted forward and backward, and also transmits a predetermined force to each vibration transmission arm 223. Gives elasticity. That is, when the end of each vibration transmission arm 223 is pressed from the body, adhesion to the back of the sound wave vibration module 211 is increased and a restoring force is formed.

The vibration transmission arm 223 is introduced through the installation hole 231 and is hinged by each rotating rod 225. At this time, one end of the vibration transmission arm 223 is in close contact with the rear surface of the sound wave vibration module 211. The vibration transmission arm 223 has a rotating structure by the rotating rod 225, but the rotation of the vibration transmission arm 223 is limited by the silicon ring 229 through the restoring force of the sound wave vibration module 211.

In the sonic vibrator 210 configured in this way, the sonic vibration module 211 is accommodated in the main body 221 and is fixed by the silicone ring 229, and the silicone ring 229 is connected to the sonic vibration module 211. ) is vibrated from the main body 221 with a predetermined elasticity. At least two vibration transmission arms 223 fastened to the main body 221 have a structure that can be rotated by a rotating rod 225, but are in close contact with the back of the sound wave vibration module 211 and by a silicon ring 229. A certain amount of elasticity is granted.

The sonic vibrator 210 is installed inside the cushion 200, and a cushioning material such as waste fiber is filled between the sonic vibrator 210 and the cushion 200 to suppress the self-movement of the sonic vibrator 210, and to Maintain its unique function.

The main body 221 is connected to an external power source by wire or wirelessly, and the wired connection to an external power source is designed so that a separate external terminal protrudes out of the cushion 200, allowing wired charging or wired power to be used. On the other hand, the main body 221 is capable of supplying power by wireless power, which includes a battery inside the sonic vibrator 210 and mounting a wireless power module to provide power without modifying the appearance of the cushion 200. supply is made.

The main body 221 includes an amplification circuit for driving the sound wave vibration module 211 by receiving external power, and unlike the sound wave vibration module 211, the amplification circuit can drive a speaker for outputting a sound signal. there is. The speaker is installed separately at one end of the cushion 200, and outputs sound signals coming from the outside through the amplification circuit of the main body 221. Accordingly, the cushion 200 can be sewn into a structure that makes it easy to mount a speaker, and can be implemented as a character doll.

Meanwhile, the main body 221 receives sound signals for driving the speaker and the sound wave vibration module 211, and is equipped with a short-range communication module such as Bluetooth and ZigBee to receive sound signals provided from the user's mobile. do. Of course, it is natural that external sound signals can be provided through a wired connection depending on the need.

Accordingly, the user supports the cushion 200 at a random location and then performs Bluetooth pairing with the main body 221 using a mobile phone. The sound signal received through the Bluetooth pairing is output to the speaker, and at the same time, the sound wave vibration is transmitted to the user's body through the sound wave vibration module 211. As described above, the sonic vibration module 211 according to the present invention does not simply transmit only acoustic signals through sonic vibration, but also transmits haptic signals such as collision scenes and impact scenes provided in the video through sonic vibration, thereby improving the enjoyment of watching movies. 3D implementation is possible. In addition, not only movies, but also images such as sounds, noises, shocks, and collisions provided in virtual spaces such as the metaverse can be provided by converting them into sound wave vibrations.

Figure 5 is a configuration diagram to explain the main functions of the main body according to the present invention. As shown, the main body 221 has a charging unit 303 for receiving external power wired or wirelessly and charging the battery 305, and responds to sound signals and sound signals based on short-distance communication with the user's mobile. A main board 301 that receives a sound wave vibration signal, an amplification board 307 that outputs the sound signal provided by the main board 301 and the sound wave vibration signal with a set gain, and the sound wave vibration signal in response to the sound signal. It consists of a speaker driver 309 that drives the speaker, and a sonic vibration driver 311 that provides the sonic vibration signal to the sonic vibrator 210.

The main body 221 configured in this way receives external power through an external terminal, or charges external power to the battery 305 using a wireless power module. The charged power is provided to the main board 301 through the charging unit 303, and the main board 301 receives sound signals and sound wave vibration signals based on short-distance communication with the user's mobile. The main board 301 identifies the received sound signal and the sound wave vibration signal and provides them to the amplification board 307, which serves as a speaker driver 309 to output the sound signal to the speaker. send. In addition, the sound wave vibration signal is provided to the sound wave vibration driver 311 for driving the sound wave vibrator 210. Accordingly, the main body 221 and the sound wave vibration module 211 installed in the cushion 200 are output as sound or sound wave vibration according to the sound signal and sound wave vibration signal received from the outside.

200: Cushion 210: Sonic vibrator
211: Sonic vibration module 213: Input terminal
215: output terminal 221: main body
223: Vibration transmission arm 227: Rotating sphere
229: Silicone ring 301: Main board
303: charging unit 305: battery
307: Amplification board 309: Speaker driving unit
311: Sonic vibration driving unit

Claims (6)

A sonic vibrator 210 is installed inside a cushion 200 of a predetermined shape, and a sonic vibration cushion is filled with a cushion material between the sonic vibrator 210 and the cushion 200,
The sonic vibrator 210 includes a sonic vibration module 211 for inducing vibration in response to an acoustic signal, a main body 221 for accommodating the sonic vibration module 211, and an inside of the main body 221. A charging unit 303 is installed to convert an acoustic signal into a driving signal of the acoustic vibration module 211 and charge the battery by receiving external power, and at least two hinges on the outer peripheral surface of the main body 221. A sound wave vibration cushion, characterized in that it consists of a vibration transmission arm 223 that is coupled to transmit the rear vibration energy of the sound wave vibration module 211 to the front. According to claim 1,
The vibration transmission arm 223 is made of a metal material, has a structure bent in an arc shape, has a predetermined elasticity, and has a predetermined elasticity and folds outward when the user's body load is pressed, and the main body ( 221) A sonic vibration cushion, characterized in that it is rotated at a certain angle through a hinge provided on the outer circumferential surface. The method of claim 1 or 2,
A silicon ring 229 for elastically fixing the sonic vibration module 211 and the main body 221 to each other;
Each rotating rod 225 for rotating each vibration transmission arm 223 provided on the outer peripheral surface of the main body 221 at a predetermined angle;
Each of the vibration transmission arms 223 includes a rotating sphere 227 for accommodating the rotating rod 225; and
A sonic vibration cushion comprising an installation hole (231) for installing the vibration transmission arm (223) on the outer peripheral surface of the main body (221). The method of claim 1 or 2,
The sonic vibration module 211 is a means for experiencing an acoustic signal and includes a haptic function, and sonic vibration is achieved by a tangible signal intentionally created from the acoustic signal, and the tangible signal is provided on the metaverse. A sonic vibration cushion characterized by a signal to induce a feeling that corresponds to changes and emotional changes. delete The method of claim 1 or 2,
The main body 221 includes a charging unit 303 for receiving external power wired or wirelessly and charging the battery 305;
A main board 301 that receives sound signals and sound wave vibration signals corresponding to the sound signals based on short-distance communication with the user's mobile;
an amplification board 307 that outputs the sound signal and the sound wave vibration signal provided from the main board 301 at a set gain;
a speaker driver 309 that drives the speaker in response to the sound signal; and
A sonic vibration cushion, characterized in that it consists of a sonic vibration driver 311 that provides the sonic vibration signal to the sonic vibrator 210.