KR20180052833A - The earthquake detector - Google Patents

Abstract

The present invention relates to an earthquake sensing device in the form of a radio disposed in a house and including an earthquake sensor. The earthquake sensing device includes: a non-directional piezoelectric sensor unit for measuring data related to the progress of the earthquake and including a non-directional sensor housing having a lower surface formed by a first piezoelectric sensor, a cylindrical surface formed by a second piezoelectric sensor and an upper surface formed by a third piezoelectric sensor, and a sensor ball inserted into the non-directional sensor housing to transmit vibration to any one of the first, second, and third piezoelectric sensors when vibration occurs; and a tilt position detecting sensor including a tilt sensor housing formed in a square shape to form four edges, an infrared ray portion provided at one of the edges the tilt sensor housing, first and second phototransistors provided at the other two edges of the tilt sensor housing, and an adjusting ball inserted into the tilt sensor housing to control ON/OFF of the optical signal detection of the infrared ray portion by the first and second phototransistors according to the arrangement state of the radio. The position of the corresponding piezoelectric sensor on which the sensor ball is placed among the first, second, and third piezoelectric sensors is automatically selected to operate the piezoelectric sensor through the ON/OFF control of the first and second phototransistors for sensing the optical signal. The data measured by the sensor ball in the corresponding piezoelectric sensor is converted into a seismic value and the notification is made upon the earthquake.

Description

The earthquake detector

The present invention relates to an earthquake sensor, and more particularly, because an earthquake sensor is installed inside a radio, malfunction is not caused in the process of transmitting the progress of the sensor ball to the piezoelectric sensor, The non-directional piezoelectric sensor unit having the piezoelectric sensor in all directions can perform the notification operation according to the occurrence of the earthquake irrespective of the state in which the radio is disposed. The non-directional piezoelectric sensor unit having a simple structure, It is possible to reduce the cost and time due to the production by cooperating with the cooperation of the wealth through the detection of the earthquake. By precisely grasping the progress according to the occurrence of the earthquake and preventing the malfunction, To an earthquake sensor capable of facilitating maintenance.

In general, an earthquake is defined as a sudden change in the earth's crust, causing the earthquake to propagate to the earth's surface. can do. The magnitude of an earthquake ranges from a very small earthquake, which is detected only by a sensitive seismometer, to a large earthquake, which causes extensive damage to a large area.

There are thousands of earthquakes that occur globally every day on earth, and most earthquakes are caused by large forces within the earth that affect the continent's movement, expansion of the sea bed, formation of mountains, and so on over a long period of time.

The magnitude of the earthquake damage has been increasing steadily, and the magnitude of earthquake damage is gradually increasing.

For example, on March 11, 2011, an earthquake of magnitude 9.0 occurred in Fukushima, Japan, resulting in a lot of casualties due to the earthquake and tsunami. In Korea, earthquakes with a magnitude of about 3.0 were sustained twice a year .

Recently, a powerful 5.8 magnitude earthquake has occurred in Gyeongsang Province, and the aftershocks have continued for hundreds of times, suggesting that Korea is not a safe zone for earthquakes.

Meanwhile, an acceleration sensor has been used as an earthquake monitoring technique for detecting such an earthquake, but a technique capable of replacing the acceleration sensor with an expensive one has been developed. This technique is disclosed in Korean Patent Publication No. 1998-702746, Sensor ", and " earthquake sensor "which is Japanese Patent Laid-Open No. 2010-14525.

KR 10-1998-702746 A JP 10-2010-14525 A

However, the conventional earthquake sensor described above suspends a weight having magnetism in the support so that it can flow, and detects a switch or a vibration signal formed in the surroundings according to the flow of the weight when an earthquake occurs. There is a problem in that the detection function such as the reduction in shaking is limited due to the rusting due to the additional moisture.

The conventional earthquake sensor described above is a technique for suspending a weight of an oscillator having a magnetic force by a spring and detecting the distance when the earthquake is further caused by the earthquake with a magnetic sensor and calculating a detection signal thereof. In addition, there is a problem that rust easily occurs when the above-described structures are used for a long period of time in a humid place, and there is a problem that smooth operation can not be performed when necessary due to breakdown due to a change in elasticity of the spring.

It is an object of the present invention to provide a piezoelectric sensor that prevents malfunction due to failure of the sensor ball to transmit magnitude to the piezoelectric sensor due to the presence of an earthquake sensor in the radio, Directional piezo-electric sensor unit can perform a notification operation according to the occurrence of an earthquake irrespective of the state in which the radio is disposed, and the cooperation of the non-directional piezoelectric sensor unit and the tilt- And to provide an earthquake sensor capable of reducing cost and time required for manufacturing.

Further, according to the present invention, the position of the piezoelectric sensor to be operated is selected by reading the tilt sensor value according to the arrangement state of the radio, and only the data generated from the selected piezoelectric sensor can be converted into the vibration value according to the movement of the sensor ball. In addition, it is possible to prevent the malfunction of the notification operation due to the occurrence of the earthquake, and to operate only the corresponding piezoelectric sensor according to the arrangement state of the radio, thereby reducing the failure rate of the piezoelectric sensors, An object of the present invention is to provide an earthquake detector.

According to an aspect of the present invention, there is provided a vibration sensor comprising: a vibration sensor housing having a cylindrical surface formed by a first piezoelectric sensor and a cylindrical surface formed by a first piezoelectric sensor, and a top surface formed by a third piezoelectric sensor; A non-directional piezoelectric sensor unit inserted into the direction sensor housing to constitute a sensor ball that transmits vibration to any one of the first, second, and third piezoelectric sensors when vibration occurs, and measures data of the progress of the earthquake; A tilt sensor housing formed in a square shape to form four corners; an infrared ray section provided at an edge of one of the corners of the tilt sensor housing; and a second infrared ray section provided at the other two corners of the tilt sensor housing, A tilt position selection sensor unit which is inserted into the tilt sensor housing and constitutes an adjusting ball for ON / OFF controlling the optical signal detection of the infrared ray part by the first and second phototransistors according to the arrangement state of the radio, The position of the corresponding piezoelectric sensor on which the sensor ball is placed among the first, second, and third piezoelectric sensors is automatically selected and operated through the on / off control of the first and second phototransistors for sensing the optical signal, And the data measured by the sensor ball in the corresponding piezoelectric sensor is converted into the progress value, and a notification is made in accordance with the occurrence of the earthquake. It provides a detector.

According to the earthquake sensor of the present invention, since an earthquake sensor is installed inside the radio, malfunction is not caused in the process of transmitting the progress of the sensor ball to the piezoelectric sensor, so that operation failure due to failure is prevented, Directional piezo-electric sensor unit having a piezoelectric sensor can achieve a notification operation in response to the occurrence of an earthquake irrespective of the state in which the radio is disposed. The non-directional piezoelectric sensor unit having a simple structure for detecting an earthquake, And it is advantageous to reduce cost and time due to production because it is accomplished by collaboration through cooperation.

Further, according to the present invention, the position of the piezoelectric sensor to be operated is selected by reading the tilt sensor value according to the arrangement state of the radio, and only the data generated from the selected piezoelectric sensor can be converted into the vibration value according to the movement of the sensor ball. In addition to this, it is possible to precisely grasp the occurrence of an earthquake, so that malfunction can be prevented from occurring. In addition, since only the corresponding piezoelectric sensor is operated according to the arrangement state of the radio, Decay is a useful invention.

1 is a schematic view showing an earthquake sensor of the present invention.
2 is a state diagram showing an earthquake detection sensor of the present invention.
FIG. 3 is an operating state in which the tilt position determining sensor unit and the non-directional piezoelectric sensor unit cooperate in cooperation with each other according to the arrangement state of the earthquake sensor of the present invention.

Hereinafter, the structure of the present invention will be described.

1 to 3, the present invention relates to an earthquake sensor 100 including a radio disposed in a household with an earthquake sensor. The earthquake sensor 100 includes a first piezoelectric sensor 11, Directional sensor housing 15 forming a cylindrical surface formed by the second piezoelectric sensor 12 and an upper surface formed by the third piezoelectric sensor 13, And a sensor ball 17 for transmitting vibration to any one of the first, second and third piezoelectric sensors 11, 12 and 13 at the time of occurrence of vibration to measure the data of the progress of the earthquake, A sensor unit 10; A tilt sensor housing 21 formed in a rectangular shape to form four corners; an infrared ray section 23 provided at one corner of the tilt sensor housing 21; First and second phototransistors 25 and 27 provided at the other two corners of the tilt sensor housing 21 and connected to the first and second phototransistors 25 and 27, And a tilt positioning sensor unit 20 for controlling an optical signal of the infrared ray unit 23 by ON / OFF control of the tilt position sensor unit 20. The first and second photo transistors The position of the corresponding piezoelectric sensor on which the sensor ball 17 is placed among the first, second and third piezoelectric sensors 11, 12 and 13 is automatically selected and operated through ON / OFF control of the first and second piezoelectric sensors 25 and 27, The data measured by the sensor ball 17 in the corresponding piezoelectric sensor is converted into the progress value Characterized in that the fulfill the notification according to occur.

Here, the earthquake sensor 200 includes a function switch 201 for selecting operation, a volume switch 202 for adjusting the volume of sound, a speaker 203, and an AM / FM selection knob A channel selection knob 205 for frequency change, a rechargeable battery (not shown) and a charging pin (not shown) for portable use, Since the notification operation of the sensor 100 can be automatically accomplished through a known normal control, a detailed description will be omitted.

In the present invention, in order to use the earthquake sensor 200, which is made up of radio, in a more specific manner in case of an earthquake, a LED 210 lighting illuminates the surroundings using a rechargeable battery, a self- (Not shown) for charging a portable electronic device such as a mobile phone 230 and a smart phone is further preferably included in the earthquake sensor 200. It is preferable that the magnitude of the intensity measured through the non- And a RECCO system (not shown) for notifying a location in a situation such as isolation or landfill.

Hereinafter, the seismic sensor 100 including the non-directional piezoelectric sensor unit 10 and the tilt positioning sensor unit 20 will be described in detail.

First, the non-directional piezoelectric sensor unit 10 is configured to measure the magnitude of the data measured by the sensor ball 17 in the piezoelectric sensor in the event of an earthquake, ).

Since the non-directional sensor housing 15 is formed in a cylindrical shape, the non-directional sensor housing 15 is composed of a bottom surface, a top surface, and a cylindrical surface connecting the bottom surface and the top surface. Respectively.

That is, the lower surface of the non-directional sensor housing 15 is formed by the first piezoelectric sensor 11, the cylindrical surface is formed by the second piezoelectric sensor 12, and the upper surface is formed by the third piezoelectric sensor 13 And is configured to be capable of detecting vibrations through all the surfaces of the non-directional sensor housing 15, respectively.

In addition, the non-directional piezoelectric sensor unit 10 further includes a sensor ball 17 inserted into the non-directional sensor housing 15, The vibration of the sensor ball 17 is transmitted to only one of the first, second, and third piezoelectric sensors 11, 12, and 13 so that the data corresponding to the earthquake can be converted into the progress of the measurement. The degree of progress is displayed through the display 206 of the radio-made earthquake sensor 200 and the notification operation is performed through the control of the known normal control unit so as to allow the nearby person to perform a rapid evacuation do.

2 and 3 of the non-directional sensor housing 15 configured in the non-directional piezoelectric sensor unit 15 according to the arrangement state of the earthquake sensor 200, Only one of the piezoelectric sensors 11, 12, and 13 is turned ON.

That is, the position of the piezoelectric sensor to be turned ON and the position of the piezoelectric sensor to be turned OFF are selected by reading the tilt sensor value of the tilt position determining sensor unit 20 according to the state where the earthquake sensor 200 is arranged or tilted uprightly, The tilt sensor housing 21 is formed in a rectangular shape to form four corners.

In order to turn on / off the piezoelectric sensors, an infrared ray portion 23 for generating an optical signal is installed at one corner of the tilt sensor housing 21, The first and second phototransistors 25 and 27 for detecting an optical signal generated in the infrared ray portion 23 are provided in opposite directions to each other.

The tilt sensor housing 21 is provided with an adjustment for turning on / off the sensing of the optical signals in the first and second phototransistors 25 and 27 according to the arrangement state of the earthquake sensor 200, And the detection and blocking operation of the optical signal by the infrared ray portion 23 and the first and second phototransistors 25 and 27 and the control ball 29 It is preferable that nothing is formed at the corner in the direction opposite to the direction in which the infrared ray portion 23 is installed so as to be smoothly performed.

In the present invention, the infrared ray portion 23 is located at the first corner 21a or the third corner 21c, which is the lower corner of the tilt sensor housing 21, and the infrared ray portion 23, It is preferable that the first and second phototransistors 25 and 27 for sensing the optical signal of the infrared ray are installed at the second and third corners 21b and 21c which are the front and rear corners in the direction opposite to each other. The first and second piezoelectric sensors 11, 12 and 13 are positioned at the lower edge of the tilt sensor housing 21, that is, at the first corner 21a, The position of the corresponding piezoelectric sensor on which the sensor ball 17 is placed can be easily selected and operated.

3A, when the bottom portion of the radio is brought into contact with the floor, the adjustment ball 29 inserted into the tilt sensor housing 21 is rotated by gravity The optical signal is not generated in the infrared ray portion 23 and the first and second phototransistors 25 and 26 are not operated. The detection of the optical signals by the first and second phototransistors 25 and 27 is turned off and the detection of the optical signals by the first and second phototransistors 25 and 27 is turned off. , The three piezoelectric sensors 12 and 13 are turned OFF and only the first piezoelectric sensor 11 on the lower surface on which the sensor ball 17 is placed is turned ON so that the first piezoelectric sensor 11 performs the measurement of the magnitude .

3A, the adjustment ball 29 inserted into the tilt sensor housing 21 is moved by the action of gravity so that the first phototransistor (the first phototransistor) The first phototransistor 25 or the second porter transistor 23 is closed so that the optical signal generated in the infrared ray section 23 is outputted to either the first phototransistor 25 or the second porter transistor 27 The first and second porter transistors 25 and 27 detect ON / OFF of the optical signal ON / OFF of the first and second porter transistors 25 and 27, 3 piezoelectric sensors 11 and 13 are turned OFF and only the second piezoelectric sensor 12 on the cylindrical surface on which the sensor ball 17 is placed is turned ON so that the second piezoelectric sensor 12 measures the degree of progress .

3A, when the radio is disposed in a state of being inverted by 180 degrees, the adjustment ball 29 inserted into the tilt sensor housing 21 is inserted into the fourth corner 21d, which is not installed by gravity, The optical signals of the first and second phototransistors 25 and 27 are all turned on because the optical signals of the first and second phototransistors 25 and 27 are all turned on. The first and second piezoelectric sensors 11 and 12 in which the sensor ball 17 is not placed are turned off as shown in part D of FIG. 3B through the optical signal ON detection, and the third and fourth piezoelectric sensors 11 and 12, Only the piezoelectric sensor 13 is turned ON, and the third piezoelectric sensor 13 performs the measurement of the magnitude.

As described above, when the earthquake sensor 100 according to the present invention is used, even if the earthquake sensor 200 is disposed in a collapsed state, it is possible to prevent the earthquake from being erroneously detected It is possible to perform the magnitude measurement only in the piezoelectric sensor in which the sensor ball is located through cooperation between the tilt position propagation sensor unit 20 and the non-directional piezoelectric sensor unit 10, It is possible to reduce the occurrence of faults caused by malfunctions, thereby facilitating maintenance, and reducing the manufacturing cost and time.

10: non-directional piezoelectric sensor unit 11, 12, 13: first, second and third piezoelectric sensors 15: non-directional sensor housing 17:
20: tilt position selection sensor part 21: tilt sensor housing 23: infrared ray part 25, 27: first and second photo transistors 29:
100: Earthquake sensor
201: Function switch 202: Volume switch 203: Speaker 204: AM / FM selection knob 205: Channel selection knob 206: Display 210: LED 230:
200: Earthquake detector

Claims (3)

An earthquake sensor comprising a radio disposed in a household with an earthquake sensor,
The earthquake detection sensor (100)
A non-directional sensor housing 15 forming a lower surface formed by the first piezoelectric sensor 11 and a cylindrical surface formed by the second piezoelectric sensor 12 and an upper surface formed by the third piezoelectric sensor 13; A sensor ball 17 for transmitting vibration to any one of the first, second and third piezoelectric sensors 11, 12 and 13 when the vibration is generated is inserted in the inside of the sensor 15, A non-directional piezoelectric sensor unit (10) for measuring data;
A tilt sensor housing 21 formed in a rectangular shape to form four corners; an infrared ray section 23 provided at one corner of the tilt sensor housing 21; First and second phototransistors 25 and 27 provided at the other two corners of the tilt sensor housing 21 and connected to the first and second phototransistors 25 and 27, And a tilt positioning sensor unit 20 constituting an adjustment ball 29 for ON / OFF-controlling the optical signal detection of the infrared ray portion 23 by the tilt position sensor 27,
The first and second piezoelectric transducers 11, 12 and 13 are connected to the corresponding piezoelectric sensors 17 on which the sensor balls 17 are placed through ON / OFF control of the first and second phototransistors 25 and 27, And the data measured by the sensor ball (17) in the corresponding piezoelectric sensor is converted into a progress value to notify the user of the occurrence of an earthquake.
The apparatus according to claim 1, wherein the infrared ray section (23) is located at a lower edge or an upper corner of the tilt sensor housing (21), and the first and second photo transistors 25 and 27 are provided at the corners opposite to each other so that the position of the corresponding one of the first, second and third piezoelectric sensors 11, 12 and 13 And the sensor is automatically selected and operated.
2. The apparatus according to claim 1, wherein the infrared ray section (23) is located at the lower edge of the tilt sensor housing (21) and comprises first and second phototransistors (25, 27) for sensing the optical signal of the infrared ray section Are provided at the front and rear edges facing each other,
When the lower part of the radio is disposed so as to abut the floor, both of the optical signals of the first and second phototransistors 25 and 27 are turned off by the adjustment ball 29 gravity-moved to close the infrared ray part 23 The first piezoelectric sensor 11 located on the underside of the non-directional sensor housing 15 is operated due to the OFF detection of the first and second phototransistors 25 and 27 and the vibration of the sensor ball 17 is detected by the first piezoelectric Can be sensed by the sensor 11,
The first and second phototransistors 25 and 25 are moved by the adjustment balls 29 gravity-shifted to close the first phototransistor 25 or the second phototransistor 27, The second piezoelectric sensor 12 located on the cylindrical surface of the non-directional sensor housing 15 is operated so that the vibration of the sensor ball 17 Can be detected by the second piezoelectric sensor 12,
When the upper surface of the radio is placed in contact with the bottom, both the optical signal sensing of the first and second phototransistors 25 and 27 are ON and the ON and OFF of the first and second phototransistors 25 and 27 The third piezoelectric sensor 13 located on the upper surface of the direction sensor housing 15 is operated to detect the vibration of the sensor ball 17 by the third piezoelectric sensor 13. [

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