KR200424918Y1 - External vibration adaptive smart garment - Google Patents

Abstract

The present invention relates to an external vibration adaptive smart clothing that is able to change the color of the optical fiber garments adaptively to the external vibration.

The external vibration adaptive smart clothing according to the present invention includes an optical fiber garment including an optical fiber, a vibration sensor coupled to the optical fiber garment to detect external vibration of the optical fiber garment, and one end of the optical fiber constituting the optical fiber garment. And a red / green / blue LED for outputting light of a predetermined color, and a color control module for changing the output light of the red / green / blue LED to correspond to the vibration level applied from the vibration sensor. It features.

Description

External vibration adaptive smart garment

1 is a view schematically showing the configuration of the external vibration adaptive smart clothing according to the present invention.

Figure 2 is a view for explaining the shape of the optical fiber 110 in the optical fiber garment 100 shown in FIG.

Figure 3 is a block diagram showing the functional separation of the internal configuration of the color control module 200 shown in FIG.

Figure 4 is a block diagram showing the functional separation of the internal configuration of the vibration sensor 220 shown in FIG.

5 is a view illustrating another configuration of the LED driving unit 250 shown in FIG.

6 to 8 are views for explaining another configuration of the coupling member 300 shown in FIG.

FIG. 9 is a block diagram showing functional separation of another internal configuration of the color control module 200 shown in FIG.

10 is a view illustrating a coupling form of the vibration sensor 220 and the vibration sensor 220 and the optical fiber garment 100 shown in FIG.

******* Brief description of the main parts of the drawing *******

100: optical fiber clothing, 110: optical fiber,

120: general thread, 200: color control module,

210: LED, 220: vibration sensor,

230: controller, 240: LED connector,

250: LED driver, 260: clock generator

270: external device connector, 280: power supply unit,

290: sensor connector.

The present invention relates to an external vibration adaptive smart clothing that is able to change the color of the optical fiber garments adaptively to the external vibration.

In general, optical fiber has been widely used in electrical, electronics, communication, medical, optical field, etc. Recently, the optical fiber is also used for various decorative purposes by utilizing the property that light can be conducted from one end to the other in the longitudinal direction. The range of use is expanding.

In the conventional clothes, bags, hats, interior articles, etc. using optical fibers, optical fibers are disposed on a fabric in a desired form, and a light emitting device such as an LED and a driving module for driving the light emitting device are provided inside the fabric. It consists of. Then, the light is emitted to the end of the optical fiber of the fabric through a method of supplying a predetermined power to the LED from the drive module to blink the LED so that a desired form, for example, a predetermined advertisement pattern is emitted.

However, in the above-described conventional products, since the electrically driven driving module is integrally attached to the fabric, the washing of the fabric is difficult. In addition, the configuration to emit light through the end of the optical fiber has to ensure the radius of curvature of the optical fiber, there is a difficulty in placing the fabric and the optical fiber combined.

Also, in the related art, the color of the fabric may be variously changed in order to emphasize the effect of advertising or decoration and the method of weaving the fabric by using the optical fiber as the warp or weft of the fabric. The proposed method (Korean Utility Model Publication No. 2000-0008770) has been proposed. These designs arrange optical fiber bundles and various colored light emitting diodes along the contours formed on the garments to selectively flash the light emitting diodes so that light of various colors is emitted through the ends of the optical fiber bundles.

However, in the above-described design, since the optical fiber bundles are separately coupled to light emitting diodes of different colors, the coupling between the light emitting diodes is complicated and the coupling thereof is limited. In other words, there is a disadvantage that the changeable color is limited.

Therefore, the present invention was devised in view of the above circumstances, but it was possible to vary the color or brightness of the optical fiber garments in various ways, but to adapt the external vibration to the various colors of the optical fiber garments. Its technical purpose is to provide clothing.

External vibration adaptive smart clothing according to the present invention for achieving the above object is a fiber optic garment comprising an optical fiber, a vibration sensor for sensing the external vibration of the optical fiber garments coupled to the optical fiber garments, and the optical fiber garments A red / green / blue LED that outputs light of a predetermined color to one end of the optical fiber to be configured, and a color control module that controls to change the output light of the red / green / blue LED to correspond to the vibration level applied from the vibration sensor. It is characterized by comprising a.

In addition, the color control module is characterized in that the control to change the color of the red / green / blue LED composite light to correspond to the vibration level.

In addition, the color control module is characterized in that the control to change the brightness of the red / green / blue LED composite light to correspond to the vibration level.

The vibration sensor may include a condenser microphone, a bandpass filter for filtering only a frequency band signal of 100 Hz or less among signals applied from the condenser microphone, an amplifier circuit for a predetermined level amplification of a signal applied from the bandpass filter, and an amplifying circuit. Rectifying the signal is characterized in that it comprises a rectifying circuit for providing to the color control module.

In addition, the optical fiber clothing and the color control module are coupled to each other through a coupling member, one end of the optical fiber of the optical fiber clothing is fixedly coupled to one end of the coupling member, the other end in a position spaced apart from one end of the optical fiber It is characterized in that the red / green / blue LED of the color control module is fixedly coupled.

In addition, the coupling member is coupled to one end of the optical fiber of the optical fiber clothing and the other end of the socket is configured in an open form, the red / green / blue LED is fixed to the inside of the jack to be detachable with the socket It is characterized in that the configuration.

In addition, the color control module is coupled to the vibration sensor for sensor power supply and signal input and output processing to the vibration sensor, and coupled to the red / green / blue LEDs to supply power to the red / green / blue LEDs LED coupling unit for performing a predetermined, LED driving unit for providing a predetermined driving signal to the red / green / blue LED through the LED coupling unit, a power supply unit for providing power supply to each device, and based on the voltage level applied from the vibration sensor It characterized in that it comprises a controller for providing a PWM control signal for driving the LED to the LED driving unit so that the corresponding composite light is output.

That is, according to the above, the color corresponding to the external vibration is output to the optical fiber clothing generated by weaving the optical fiber by sensing the external vibration or the brightness of the output color is changed, so that the color of the optical fiber clothing can be changed in various ways. do.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a view showing a schematic configuration of an external vibration adaptive smart clothing according to the present invention.

As shown in FIG. 1, the external vibration adaptive smart clothing according to the present invention includes an optical fiber garment 100 configured by weaving an optical fiber 110 and a red / green / blue LED to correspond to external vibration (210: 211, 212, 213). In addition to changing the color or the brightness of a specific color of the generated synthetic light, and is provided with a color control module 200 for providing the synthesized light to the end of the optical fiber 110 of the optical fiber garment (100).

In this case, the optical fiber garment 100 may be a garment of various forms such as a jacket, pants, shirt, vest, blouse, underwear formed by weaving the optical fiber 110 and the general thread 120. And, considering that the optical fiber 110 constituting the optical fiber garment 100 has a transparent characteristic, it may be provided with an inner shell having an opaque characteristic inside the optical fiber garment 100, the optical fiber in the optical fiber garment 100 110 may be configured to form only a portion of the garment.

In addition, the optical fiber garment 100 may be configured such that an accommodation space such as a pocket (not shown) for accommodating the color control module 200 is provided inside or outside thereof.

In addition, the optical fiber 110 constituting the optical fiber garment 100 may be configured to form the weft or inclination of the optical fiber garment 100 in the form of two or more optical fiber bundles.

In addition, the optical fiber 110 in the optical fiber garment 100 is a side of the optical fiber (100 in the direction of the arrow in the direction of the arrow) toward the outer side of the optical fiber garment 100, as shown in Figure 2a optical fiber 110 The predetermined grooves 113 are formed in the cladding layer 112 surrounding the core layer 111, which is an optical path of the optical fiber, at regular intervals, so that the light present in the core layer 111 is easily transferred through the grooves 113. Configured to diverge out of 110. In addition, as shown in FIG. 2B, the bundle type optical fiber 110 may be configured to be surrounded by a protective cover 114 such as a material having transparency on the outside thereof, such as vinyl.

On the other hand, the optical fiber 110 end of the optical fiber garment 100 and the red / green / blue LED (210: 211, 212, 213) of the color control module 200 as shown in Figure 1 is a separate coupling member 300 It is combined in the form of spaced apart from each other through. That is, one end of the coupling member 300 is fixedly coupled to the end of the optical fiber 110 of the optical fiber garment 100, the other side of the red / green / blue LED of the color control module 200 (210: 211, 212, 213) Is fixedly coupled. In this case, the separation distance between the optical fiber end and the LED 210 is set such that the optical fiber end is disposed at a position where the output light of each of the red / green / blue LEDs 210: 211, 212 and 213 are synthesized. The red / green / blue LEDs 210, 211, 212, and 213 are inclined about 30 ° with respect to the central axis so that the output light is synthesized at a predetermined distance. In addition, the red / green / blue LEDs 210: 211, 212, and 213 may be configured as separate LEDs or RGB LEDs 210 having red / green / blue colors.

In addition, in FIG. 1, the color control module 200 detects the red / green / blue LED 210 and the external vibration as shown in FIG. 3, and outputs a voltage value corresponding to the vibration level 220. ), A controller 230, an LED connector 240 coupled to the red / green / blue LED 210, and a predetermined control signal for driving the LED 210 based on a control signal applied from the controller 230. The LED driver 250 for providing the red / green / blue LED 210 through the LED connector 240, the clock providing unit 260 for providing a predetermined operation clock to the controller 230, an external device For example, an external device connector 270 for receiving a predetermined operation program for overall operation of the controller 230 from an external device in combination with a program providing device, and each device constituting the color control module 200 with a predetermined driving power supply. It is configured to include a power supply unit 280 to provide.

Here, the vibration sensor 220 provides a voltage signal corresponding to the sensed vibration level to the controller 230. That is, the vibration sensor 220 is a low frequency band, such as the frequency domain of the tapping or vibration of the condenser microphone 221, the external frequency applied from the condenser microphone 221, as shown in FIG. A band pass filter 222 for filtering only signals in a region of ˜100 Hz, an amplifying circuit 223 for outputting a low level of amplified signal from the band pass filter 222 by a predetermined level, and a signal applied from the amplifying circuit 223. It is configured to include a rectifier circuit 224 provided to the controller 230 by rectifying. In more detail, the condenser microphone 221 is usually implemented as a condenser C1, one end of which is coupled to the power input terminal Vcc through an impedance matching resistor R1, and the other end thereof is grounded. The band pass filter 222 is connected to the capacitor C2 and the resistor R2 in series between the contact between the impedance matching resistor R1 and the capacitor C1 and the ground, and the capacitor C2 and the capacitor C2. The resistor R3 and the capacitor C3 are connected in series between the contact between the resistor R2 and the contact between the resistor R2 and the ground. In addition, the amplifying circuit 223 includes a variable resistor VR, an amplifier AMP for amplifying a signal provided from a contact between the resistor R and the capacitor C, a variable resistor VR, and a variable variable. The resistor R4 is coupled between the resistor VR and the amplifier AMP, and the amplification level of the amplifier AMP is set by the variable resistor VR and the resistor R4. In addition, the rectifier circuit 224 is configured by coupling a resistor R5 between the bridge circuit B and both ends of the bridge circuit B.

In addition, the controller 230 receives a predetermined operation program provided from an external device through the external device connector 270 and stores it in a predetermined data memory (not shown). At this time, the operation program is configured to include the LED driving information for the voltage corresponding to the vibration level provided from the vibration sensor 220, the LED driving information is the color information according to the voltage level or the brightness for a specific color It can be information. The driving information is a color control signal according to a pulse width modulation (PWM) method, which is driving time information for each color of red, green, and blue. In addition, the controller 230 includes an AD converter 231 for converting an analog voltage signal applied from the vibration sensor 220 into a digital signal, and is configured using ATMEL's "ATmega 128 16 AI". Can be.

In addition, the LED connector 240 and the sensor connector 260 and the LED 210 and the sensor connector 260 is electrically connected to a predetermined level of the power supplied from the power supply unit 280 and the LED connector 240 It is provided to the vibration sensor 220 electrically connected.

In addition, the LED driver 250 is a drive control unit 251 for outputting a predetermined level of the LED drive current for a predetermined time based on the color control signal applied from the controller 230, the drive control unit 251 and the It is configured to include a protection resistor (R) coupled between the LED connector 240 to perform mutual impedance matching. In this case, the driving control unit 251 may be configured using, for example, "TD62083AF" manufactured by TOSHBA, in which eight transistors are Darlington coupled. In addition, as shown in FIG. 3, the driving control unit 251 is coupled to the eight data lines of the controller 230, and each output terminal is coupled to the LED connector 240 through the protection resistor R. FIG. . Herein, the LED connector 240 has an output terminal coupled to the LED 210, and three output terminals for red / green / blue of the driving control unit 251 are coupled to each input through each protection resistor R. In the present invention, two driving controllers 251 may be provided to be coupled to four LEDs 210 through four LED connectors 240. In addition, in the present invention, as shown in FIG. 5, the second protection resistor R2 is further coupled to the output terminal of the driving control unit 251 so that the second LED connector 241 coupled to the general LED is further coupled. It is possible to carry out. That is, it can be implemented to selectively combine the normal LED or RGB LED as needed.

3, the power supply unit 280 includes a battery 281, a battery connector 282 for coupling with the battery 281, for example, a regulator 283 for providing a rated voltage of " 5V " A power switch 284 is coupled between the connector 282 and the regulator 283 to control the supply of power to the regulator 283. Although not shown, the power supply unit 280 may be configured to further include a predetermined light emitting device for light emitting display of the power supply state of the regulator 283.

In addition, in the present invention, as shown in Figure 6, the coupling member 300 for coupling the optical fiber garment 100 and the color control module 200 may be configured in a removable form. That is, the coupling member 300 collects and fixes one end of the optical fiber 100 of the optical fiber garment 100, and the socket 310 for introducing light of a predetermined color to the end of the optical fiber 110, and the socket 310 And a red / green / blue LED 210 therein configured to be detachable and providing light of a specific color generated by the LED 210 to an end of the optical fiber 110 of the socket 310. It consists of a jack 320 for.

As shown in FIG. 7, the socket 310 has a cylindrical case 312 formed with a groove 311 through which one side is opened and the optical fiber 110 is introduced. In addition, a predetermined fixture 313 for fixing the optical fiber 110 introduced into the groove 311 is coupled to the inside and the outside of the case 312 in which the groove 311 is formed.

In addition, the jack 320 is configured to be fitted to the inside of the case 312 through the opening of the socket 310 as shown in Figures 7 and 8. Jack 320 is a silicon frame formed with a first to third LED insertion groove 322 for fitting the LED 210 of the red / green / blue to one side opening of the cylindrical case 321, which is open on both sides ( 323 is combined. The first to third LED insertion grooves 322 formed in the silicon frame 323 have the output light of the red / green / blue LEDs 210 in the state in which the socket 310 and the jack 320 are fastened. It is configured to be inclined about 30 ° relative to the central axis to meet at the cross section of the optical fiber (110). That is, light of a specific color generated by synthesizing the output light of the red / green / blue LED 210 is introduced into the cross section of the optical fiber 110.

On the other hand, the vibration sensor 220 may be configured to be coupled to the controller 230 through a predetermined sensor connector 290, as shown in FIG.

In this case, the vibration sensor 220 is coupled to the sensor connector 290 through a predetermined cable (C) having a predetermined length as shown in Figure 10, to provide a signal corresponding to the vibration level to the controller 230. Can be configured. The vibration sensor 220 may have a general button shape as shown in FIG. 10A or a snap button shape as shown in FIG. 10B. Here, when the vibration sensor 220 has a snap button shape, the first shape 220a of the U-shape has a "-" characteristic, and the second shape 220b of the U-shape is configured to have a "+" characteristic. When the button is fastened it is configured to be electrically connected. In addition, the vibration sensor 220 is fixedly coupled to the bulk tape 220c of the first form at a predetermined position of the optical fiber garment 100, as shown in Figure 10c, the first side of the vibration sensor 220 The vibration sensor 220 may be detached from the optical fiber garment 100 by the bulk tapes 220c and 220d by combining the bulk tapes 220d of the second type corresponding to one form. In addition, although not shown, the vibration sensor 220 may be attached to the optical fiber garment 100 in the form of a waffle.

Next, the operation of the device having the above configuration will be described.

First, the user combines an external device with the external device connector 270 to load a predetermined operation program for color change according to the present invention into the controller 230. In this case, the operation program loading operation of the controller 230 may be directly performed by the user or may be performed by the manufacturer at the time of manufacturing the color control module. Then, the operation program may drive control signals for the red / green / blue LEDs 120, for example, red / green, to change the color of the detected vibration level or to change the brightness for a specific color. / Blue LED 120 is configured to include the drive time information.

Thereafter, the user mounts the color control module 200 at a predetermined position of the optical fiber garment 100. At this time, the vibration sensor 220 of the color control module 200 is disposed on the optical fiber garment 200 in the form as illustrated in FIG.

When the user turns on the power switch 284 of the power supply unit 280 in the above state, a predetermined level of power from the battery 281 is converted into a "5V" power supply voltage through the regulator 283 and each element It is provided as the operating power of.

That is, the color control module 200 is in an operating state. In this case, the operating power is provided to the vibration sensor 220 and the operating power is supplied to the LED 210 through the LED connector 240.

Subsequently, when external vibration is applied to the optical fiber garment 100 due to a user or another person tapping the optical fiber garment, the vibration sensor 220 provides a voltage signal corresponding to the vibration level to the controller 230.

The controller 230 extracts the driving time for the red / green / blue LED 210 corresponding to the voltage level provided from the vibration sensor 220 and provides the corresponding driving control signal to the driving controller 251.

The driving controller 251 provides the driving control signal provided from the controller 230 to the LED 210 through the protection resistor R and the LED connector 240. That is, the composite light color or brightness of the red / green / blue LEDs 120 is changed according to the ON driving time for the red / green / blue LEDs 120.

The synthetic light generated by the LED 210 is provided to the end of the optical fiber 110 of the optical fiber garment 100 through the coupling member 300, so that the color or brightness of the optical fiber garment 100 is automatically changed.

That is, according to the present invention, the color of the optical fiber clothing can be variously changed by outputting the color corresponding to the external vibration or changing the brightness of the output color with the optical fiber clothing generated by sensing the external vibration and weaving the optical fiber. Will be.

In addition, according to the present invention to configure the electronic portion to generate a light source to be separated from the optical fiber clothing to facilitate the washing of the optical fiber clothing.

On the other hand, the present invention is not limited to the above embodiments and can be variously modified within the scope without departing from the technical spirit of the present invention.

As described above, according to the present invention, the color or brightness of the optical fiber garment is automatically changed according to the external vibration, thereby making it possible to variously change the color of the optical fiber garment.

Claims (7)

Optical fiber garments composed of optical fiber, Vibration sensor coupled to the optical fiber garments to detect external vibration of the optical fiber garments, red / green / blue LED outputting light of a predetermined color to one end of the optical fiber constituting the optical fiber garments, vibration applied from the vibration sensor External vibration adaptive smart clothing characterized in that it comprises a color control module for controlling to change the output light of the red / green / blue LED to correspond to the level. The method of claim 1, The color control module external vibration adaptive smart clothing, characterized in that for controlling to change the color of the red / green / blue LED composite light to correspond to the vibration level. The method of claim 1, The color control module external vibration adaptive smart clothing, characterized in that for controlling to change the brightness of the red / green / blue LED composite light to correspond to the vibration level. The method according to any one of claims 1 to 3, The vibration sensor includes a condenser microphone, a bandpass filter for filtering only a frequency band signal of 100 Hz or less among the signals applied from the condenser microphone, an amplifier circuit for a predetermined level amplification of a signal applied from the bandpass filter, and a signal applied from the amplifying circuit. External vibration adaptive smart clothing, characterized in that it comprises a rectifying circuit for rectifying and providing to the color control module. The method of claim 1, The optical fiber clothing and color control module are coupled to each other through a coupling member, One end of the coupling member is fixedly coupled to one end of the optical fiber of the optical fiber clothing, and the other end is configured to be fixedly coupled to the red / green / blue LED of the color control module at a position spaced apart from the one end of the optical fiber. External vibration adaptive smart clothing. The method of claim 5, The coupling member is coupled to one end of the optical fiber of the optical fiber clothing and the other end of the socket is composed of an open form, the red / green / blue LED is fixed to the inside of the jack is configured to be detachable with the socket External vibration adaptive smart clothing, characterized in that. The method of claim 1, The color control module is coupled to the vibration sensor for sensor power supply and signal input and output processing to the vibration sensor, and coupled to the red / green / blue LED to supply power to the red / green / blue LED On the basis of the LED coupling unit to perform, LED driving unit for providing a predetermined driving signal to the red / green / blue LED through the LED coupling unit, a power supply unit for supplying power supply to each device, and the voltage level applied from the vibration sensor External vibration adaptive smart clothing, characterized in that it comprises a controller for providing a PWM control signal for driving the LED to the LED driving unit so that the corresponding composite light is output.

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