KR101126748B1 - Cervical collar - Google Patents

Abstract

The present invention relates to a cervical vertebrae guard, and more particularly, the cervical vertebrae fixing part for fixing and protecting the cervical vertebrae of the user, and provided in the cervical vertebral fixing part at the position of the neck to check the heart rate and breathing signal of the user A sensor unit for detecting heartbeat and respiration signals, a display unit for outputting heartbeat and respiration signals detected by the sensor unit, a communication module unit for transmitting heartbeat and respiration signals detected by the sensor unit to a portable terminal, and A cervical vertebrae protector comprising a sensor unit, a display unit, and a power supply unit for supplying power to a communication module unit, and a switch unit for turning on or off the state of the power supply unit.

Cervical vertebrae guards, wireless communications, heart rate, breathing.

Description

Cervical Spine Protector {CERVICAL COLLAR}

The present invention relates to a cervical vertebrae guard for fixing the neck to protect the cervical vertebrae.

In general, cervical vertebrae guards can be used to transport emergency patients damaged to the cervical spine due to various accidents such as traffic accidents or falls, or to fix the cervical vertebrae to protect the cervical spine against unconscious patients. It is used a lot in.

In particular, the spinal cavity inside the cervical spine is passed through the spinal cord and cervical nerves, motor neurons are transmitted from the brain to the limbs and sensory nerves delivered to the brain from each organ of the limbs and torso through the cervical spine. In addition, the autonomic nerves that control the heart rate and breathing and digestion pass around the front of the cervical spine. When fractures or dislocations occur in these cervical spines, first aid is very important because it can cause death or paralysis of the extremities.

As such, cervical vertebrae guards may be referred to as medical aids needed to enable the rescue team to fix the cervical spine of the patient at any time in case of an emergency.

However, a patient in a traffic accident or a crash accident should take emergency measures not only for the cervical spine but also for heart rate and breathing. If the site is in an urgent situation, it is not easy to check and measure heart rate and respiration.

In addition, in the case of a large accident, many casualties occur, when a relatively small number of rescue workers must grasp the state of many patients, in particular, there is a situation where there is no time to check heart rate and breathing one by one.

Technical problem to be solved by the present invention is to determine the patient's condition by measuring the heart rate and breathing at the same time as the cervical spine fixed.

In addition, the technical problem to be solved by the present invention is to be able to check the heart rate and breathing of the patient to a portable terminal away from a certain distance by wearing on the patient regardless of the place.

Cervical vertebrae guard according to one aspect of the present invention and the cervical vertebrae fixing portion to secure the cervical spine (頸椎) of the user; A sensor unit provided at the cervical spine fixing unit to detect a heartbeat and a breathing signal at a neck position at which a user may check a heartbeat and a breathing signal; A display unit provided in the cervical spine fixing unit and outputting a heartbeat and a respiration signal detected by the sensor unit; A communication module unit configured to transmit a heartbeat and a respiration signal detected by the sensor unit to a portable terminal; A power supply unit supplying power to the sensor unit, the display unit, and the communication module unit; And a switch unit for turning on or off the state of the power supply unit.

The cervical spine fixing part of the cervical vertebrae guard according to the above aspect is characterized in that it further comprises a display unit for outputting the heart rate and breathing signal detected by the sensor.

The sensor unit of the cervical vertebrae guard according to the feature is a VCO (Voltage Controlled Oscillator) or oscillator for oscillating a frequency in a radio frequency (RF) manner, a first low noise amplifier for amplifying the frequency, and the first low noise amplifier A radiating antenna for radiating the amplified frequency through a second antenna; a second low noise amplifier for amplifying the oscillated frequency and transmitting the amplified frequency to a mixer; a receiving antenna for receiving a frequency radiated from the radiating antenna; and a frequency received at the receiving antenna. It characterized by comprising a third low noise amplifier to amplify and deliver to the mixer.

The sensor unit of the cervical vertebrae guard according to the above feature is characterized in that it further comprises a signal processing unit for processing to digitize the signal input to the mixer.

The signal processor of the cervical vertebrae guard according to the above-mentioned features may include an amplifier for amplifying a frequency input from a mixer of a sensor unit, a band pass filter for passing only a limited frequency band among the amplified frequencies, and the band pass filter. Characterized in that it consists of an AD converter that converts the passed frequency into a digital signal.

The display unit of the cervical vertebrae guard according to the feature is characterized in that it further comprises a voice output unit to inform the outside through the voice or sound in accordance with the output rate of the heart rate and breathing signal is output.

The communication module unit of the cervical vertebrae guard according to the above feature is characterized by using Zigbee or Bluetooth.

According to this aspect of the present invention,

The present invention has the effect of checking the heart rate and breathing of the user in real time through the display formed on the cervical spine fixing part without fixing one by one while fixing and protecting the cervical spine of the emergency patient.

In addition, the present invention can check the heart rate and respiration of the emergency patient in real time through the portable terminal capable of wireless communication even if the rescuer is a certain distance away from the emergency patient has the effect that can take care of many patients.

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

1 is a view showing the cervical vertebrae guard according to the present invention, Figure 2 is a block diagram showing the sensor unit of the cervical vertebrae guard according to the present invention, Figure 3 is a heart rate and according to the sensor unit and signal processing unit of the cervical vertebrae guard according to the present invention A flow chart showing a respiratory detection method.

1 and 2, the cervical vertebrae guard according to the embodiment of the present invention is a cervical spine fixing unit 100, sensor unit 200, display unit 400, communication module 500, power supply unit 600 And the switch unit 700.

Here, the cervical vertebrae fixing part 100 is to protect the cervical vertebrae by fixing the cervical vertebrae of the user and protects the cervical vertebrae by wrapping around the neck using a hard cover. At this time, only the cervical spine fixing part 100 according to an embodiment of the present invention may serve as a cervical vertebrae protector.

Here, the sensor unit 200 is provided in the cervical spine fixing unit 100 to be mounted at the position of the neck to check the heart rate and breathing signal felt by the user's neck to detect the heart rate and breathing signal of the user. More specifically, the sensor unit radiates frequencies to the heart and lungs, and when the heart and lungs contract or expand, they reflect the respective frequencies. The frequency difference between the two reflected waves is used to measure heart rate and respiration by the Doppler effect.

In this case, the sensor unit VCO (Voltage Controlled Oscillator) or oscillator 210, the first low noise amplifier 220, the radiation antenna 230, the second low noise amplifier 240, the receiving antenna 260, the third low noise amplifier ( 270, and a mixer 250, and further includes a signal processor 300 to digitize the frequency input to the mixer 250.

The voltage controlled oscillator (VCO) or the vibrator 210 oscillates the frequency in a radio frequency (RF) manner.

The first low noise amplifier 220 amplifies the weak frequency at which the VCO or oscillator 210 oscillates.

The radiation antenna 230 radiates the amplified frequency to the outside through the first low noise amplifier 220.

The second low noise amplifier 240 transmits the frequency oscillated by the voltage controlled oscillator (VCO) or the oscillator 210 to the mixer 250.

The receiving antenna 260 receives a frequency radiated from the radiation antenna 230.

The third low noise amplifier 270 amplifies and transmits the frequency received from the reception antenna 260 to the mixer 250.

The mixer 250 measures the heart rate and the respiratory rate generated in the user's neck by using the difference between the frequency transmitted from the second low noise amplifier 240 and the frequency transmitted from the third low noise amplifier 270.

That is, the mixer 250 may know the user's heart rate and respiratory rate by the Doppler effect as a difference between the frequency oscillated by the VCO or the vibrator 210 and the frequency reflected from the neck of the user. In addition, the greater the difference between the frequency oscillated by the voltage controlled oscillator (VCO) or the oscillator 210 and the frequency reflected by the user's neck, the faster the heartbeat felt by the user's neck moves.

The signal processor 300 is used to convert the user's heart rate and respiration rate measured by the mixer 250 into digital signals.

The signal processor 300 includes an amplifier 310, a band pass filter 320, and an AD converter (Analog to Digita Converter, 330), and the amplifier 310 amplifies a frequency input from the mixer 250. Only a limited frequency band among the amplified frequencies is passed through the band pass filter 320, and the frequency passed through the band pass filter 320 is obtained using the AD converter 330 to obtain a heartbeat and respiration signal converted into a digital signal. Can be.

The method of detecting the heartbeat and respiration of the user using the sensor unit 200 and the signal processor 300 and converting the digital signal into digital signals will be described below.

First, a frequency is generated in the VCO or the vibrator 210 of the sensor unit 200 (S910). At this time, the VCO or the vibrator 210 uses a radio frequency (RF) method (S910).

Subsequently, the frequency is amplified by the first low noise amplifier 220 and radiated to the outside using the radiation antenna 230, and the frequency generated by the VCO or the vibrator 210 is amplified by the second low noise amplifier 240 and the mixer. In step S920, it is transmitted to (250).

Subsequently, the externally radiated frequency is received using the receiving antenna 260 and amplified by the third amplifier 270 and transmitted to the mixer 250 (S930).

Subsequently, the signal according to the difference between the frequency transmitted to the mixer 250 via the second low noise amplifier 240 and the mixer 250 via the third low noise amplifier 270 is measured (S940).

Subsequently, the signal measured by the mixer 250 is transferred to the amplifier 310 of the signal processor 300 to amplify the signal (S950).

Subsequently, the amplified signal is filtered using the band pass filter 320 only at a predetermined frequency band (S960).

Finally, the signal filtered by the band pass filter 320 is converted into a digital signal using the AD converter 330 (S970).

Here, the display unit 400 digitizes and outputs the heartbeat and respiration signals detected by the sensor unit 200. In this case, the display unit 400 may be provided at one side of the cervical spine fixing unit 100 to output the heart rate and respiration detected by the sensor unit 200 in real time.

In addition, the display unit 400, if the output heart rate and breathing signal is output faster than a certain speed or slower than a certain speed or slow output below the voice output to inform the outside through the voice or sound to inform the user of a dangerous situation 410 is further included.

In this case, the voice output unit 410 may distinguish the output signal when the heartbeat and respiration signal is output faster than a certain speed and slower than a predetermined speed, the reference of the constant speed of the heartbeat and respiration is 1 The average beats in minutes and can vary according to individual differences.

Here, the communication module 500 is formed using Zigbee or Bluetooth to transmit the heartbeat and respiration signals detected by the sensor unit 200 to the portable terminal 800.

At this time, the communication module 500 is a portable terminal (800) using the ZigBee or Bluetooth used in the embodiment of the present invention, the portable terminal 800 to the signal to check the heart rate and breathing of the user anywhere in the communication area To pass).

Therefore, there is an effect that can monitor the user's heart rate and breathing through the portable terminal 800 at a certain distance away.

Further, in the embodiment of the present invention, the communication module 500 is limited to Zigbee or Bluetooth, but is not limited thereto.

Here, the power supply unit 600 supplies power to the sensor unit 200, the display unit 400, and the communication module unit 500.

Here, the switch 700 controls the ON or OFF of the power supply 600.

As described above, in the detailed description of the present invention has been described with respect to preferred embodiments of the present invention, those skilled in the art to which the present invention pertains without departing from the scope of the present invention Of course, variations are possible. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the equivalents as well as the claims that follow.

1 is a view showing a cervical vertebrae protector according to the present invention.

Figure 2 is a block diagram showing the sensor unit of the cervical vertebrae protector according to the present invention.

3 is a flow chart illustrating a heart rate and respiration detection method according to the sensor unit and the signal processing unit of the cervical spine guard according to the present invention.

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

100 cervical spine fixing part 200: sensor part

210: VCO or oscillator 220: first low noise amplifier

230: radiation antenna 240: second low noise amplifier

250: Mixer 260: receiving antenna

270: third low noise amplifier 300: signal processing unit

310: amplifier 320: band pass filter (BPF)

330; AD converter 400: display unit

410: audio output unit 500: communication module unit

600: power supply unit 700: switch unit

800: portable terminal

Claims (7)

Cervical vertebrae fixing part for fixing and protecting the cervical vertebrae of the user; A sensor unit provided at the cervical spine fixing unit to detect a heartbeat and a breathing signal at a neck position at which a user may check a heartbeat and a breathing signal; A display unit provided in the cervical spine fixing unit and outputting a heartbeat and a respiration signal detected by the sensor unit; A communication module unit configured to transmit a heartbeat and a respiration signal detected by the sensor unit to a portable terminal; A power supply unit supplying power to the sensor unit, the display unit, and the communication module unit; And Cervical vertebrae guards, characterized in that configured as a switch unit to turn on (ON) or off (OFF) the state of the power supply. delete The method of claim 1, The sensor unit is a VCO (Voltage Controlled Oscillator) or oscillator for oscillating the frequency in a radio frequency (RF) method, A first low noise amplifier for amplifying the frequency; A radiation antenna radiating the frequency amplified by the first low noise amplifier; A second low noise amplifier for amplifying and transmitting the oscillated frequency to a mixer; A reception antenna for receiving a frequency radiated from the radiation antenna; And a third low noise amplifier configured to amplify the frequency received from the receiving antenna and transmit the amplified frequency to the mixer. The method of claim 3, The sensor unit cervical vertebrae guards, characterized in that further comprises a signal processing unit for processing to digitize the signal input to the mixer. 5. The method of claim 4, The signal processing unit and an amplifier for amplifying the frequency input from the mixer of the sensor unit, A band pass filter for passing only a limited frequency band among the amplified frequencies, and Cervical vertebrae protector, characterized in that it comprises an AD converter for converting the frequency passed through the band pass filter into a digital signal. The method of claim 1, The display unit cervical vertebrae guards, characterized in that it further comprises a voice output unit to inform the outside through the voice or sound in accordance with the output rate of the heart rate and breathing signal output. The method of claim 1, The communication module unit is a cervical spine guard, characterized in that using Zigbee (Bluetooth) or Bluetooth (Bluetooth).

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