KR101492593B1 - Collateral surveillance system with Low Power Collateral device and thereof. - Google Patents

Abstract

The present invention relates to a collateral monitoring system including a collateral terminal used to monitor the status of a collateral object with low power and a method thereof. More specifically, the present invention relates to a collateral monitoring system including a collateral terminal which can be operated with low power to use a battery for an extended period of time to monitor the collateral object; and a method thereof. The present invention includes a central management server and the collateral terminal installed on the collateral object to check the event and risk signs occurring on the collateral terminal periodically and immediately without visiting the collateral object. The collateral terminal is built to be operated with low power to extend the life of the battery.

Description

TECHNICAL FIELD The present invention relates to a collateral surveillance system having a low-power collateral terminal and a collateral surveillance system and a method thereof.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a system and method for monitoring a collateral having a collateral terminal for monitoring the state of a collateral with a low power, and more particularly to a collateral monitoring system for monitoring a collateral, The present invention relates to a security monitoring system and a method thereof.

According to the present invention, a collateral is provided to a creditor as a collateral for a debtor in a secured loan; Wherein the event information includes at least one of a first occurrence value of the fluctuation symptom and a time lapse after the first occurrence value of the fluctuation symptom, And a change occurrence value according to the change occurrence value; A central management server that receives and manages event information generated in a collateral terminal through a wired and wireless communication network; And a monitor terminal for checking the status of the collateral according to the event information and / or the degree of danger sent from the central management server through a wired or wireless communication network,

Wherein the collateral terminal is designed with a low power and transmits abnormality data to the central management server periodically.

Accordingly, the present invention can check the event of the collateral generated by the collateral terminal operating at low power and the degree of danger at any time, so that it is possible to immediately check the change of the collateral without visiting, thereby preventing the collapse of the collateral, It is possible to use the security terminal for a long period of time.

Generally, the types of loans of financial institutions include credit loans, chartered funds, student loans, and secured loans.

Among them, mortgage loan means the means provided to the creditor in order to secure the debtor in case of default of the debtor, or the preservation of the disadvantage that the other person may suffer in the future.

Such mortgage loans include personal collateral and physical collateral.

The personal security means a method by which not only the general property of the debtor but also the third person other than the debtor shall be liable to the general property of the person, Real estate, movable property, and bonds are provided as collateral, and the creditor has the right to override the property first.

This item belongs to the general property of the debtor, but, in particular, for the purpose of physical security, the creditor who holds the lien takes priority over the general creditor and receives payment from the object.

Of course, setting up physical security is not limited to the debtor, so it may provide what the third party other than the debtor owns as collateral for the debtor's debts.

Here, the creditor is often a financial institution.

As shown in FIG. 1, the financial institution 10, which is a creditor, borrows a certain amount of money based on the mortgage, which is collateral provided by the debtor 20 (for example, It does.

After making the loan, the financial institution 10 checks the credit status and the status of the collateral provided at all times.

In other words, the management staff (30, branch banker) of the creditor (10) visits the site of the collateral (machine tool) provided by the debtor (20) on a weekly or monthly basis to grasp the state of the collateral, photographs the collateral, Institution, 10).

However, when most management staff (30) visit the site where the collateral is located, it is often the case that the debtor who owns or manages the collateral makes or hinders confirmation for various reasons.

This is because the debtor disposes of the collateral arbitrarily for various reasons such as bankruptcy without informing the creditor.

In this case, unlike the contract terms of the loan, there is a problem that the value of the collateral is extinguished or the possession of legal disputes becomes large.

3 is a specific configuration diagram of a collateral terminal according to a conventional technique developed by the inventor of the present application.

3, disclosed in Korean Patent Registration No. 10-1260481, the conventional security terminal 120 includes a gyro sensor module 121, a vibration sensor module 122, a position tracking sensor module 123, A power sensor module 124, and a control module 129.

First, the gyro sensor module 121 is a module for interfacing between the gyro sensor provided in the collateral terminal 120 and the control module 129, and measures the movement of the collateral 110 using the gyro sensor.

Such a gyro sensor senses the angular velocity to measure the movement of the collateral 110.

It can be seen that the movement of the collateral 110 is moving when the movement continues or the size changes from time to time.

The vibration sensor module 122 is a module for interfacing between the vibration sensor provided in the collateral terminal 120 and the control module 129 and measures the vibration generated in the collateral 110 using the vibration sensor.

The vibration sensor is also referred to as a sound sensor or an acceleration sensor.

If vibration continues or changes in size from time to time, it can be seen that the collateral 110 is moving to another location.

The location tracking sensor module 123 is a module for interfacing between the position tracking sensor provided in the collateral terminal 120 and the control module 129 and tracks the position and movement of the collateral terminal 120 using a position tracking sensor .

In order to track the location and movement of the collateral terminal 120, the location tracking sensor communicates with the GPS to acquire and process the location information from the GPS.

If the location information is changed frequently, it can be known that the collateral 110 is moving when compared with the first location information.

The power sensor module 124 is a module for interfacing between the power sensor provided in the collateral terminal 120 and the control module 129. The power sensor module 124 measures the presence or absence of power used in the collateral 110 by using a power sensor.

For example, if the collateral 110 is still being used, the normal amount of power will be checked, and if not, the abnormal amount of power will be checked.

The thermal measurement sensor module 129a is a module for interfacing between the thermal measurement sensor provided in the collateral terminal 120 and the control module 129. The thermal measurement sensor module 129a measures the heat generated from the collateral using the thermal measurement sensor.

Such thermal sensing is suitable for particular collateral 120, e.g., a collateral 120 that normally generates heat.

Finally, the control module 129 controls the data flow between the gyro sensor module 121, the vibration sensor module 122, the position tracking sensor module 123, the power sensor module 124 and the thermal sensor module 129a In addition, it controls data flow between the special key lock module 125, the battery module 126, the LED lock module 127, and the communication module 128.

As described above, by monitoring various signs of the collateral 110 by using various sensors, the creditor can immediately deal with the fluctuation situation in advance.

In addition to the gyro sensor module 121, the vibration sensor module 122, the position tracking sensor module 123, the power sensor module 124, the control module 129 and the thermal measurement sensor module 129a, A special key lock module 125, a battery module 126, an LED lock module 127, and a communication module 128.

The special key lock module 125 is installed at the lower end of the collateral terminal 120 and receives the cancel command through the special key to receive the special key lock module 125 and the collateral 110 from the collateral 110, Let it go.

The special key lock module 125 prevents the collateral terminal 120 installed in the collateral 110 from being separated, thereby maintaining the inherent function of the collateral terminal 120.

This special key lock module 125 is a module required under the assumption of the worst case.

Next, the battery module 126 continuously supplies standby power to each module through the charged power source when power is not supplied to each module.

At this time, if the power is not supplied, the debtor must forcibly cut off the power supply or prevent the power supply from being cut off due to the power failure.

However, it is legally illegal for the debtor to shut off the power supply, so the power supply by the battery module must be considered in mind, so a low-power-operated collateral terminal is needed.

Accordingly, each module operates according to the standby power source, so that it is possible to continuously detect a fluctuation symptom.

And informs the central management server (140) and / or the monitor terminal (150) as event information.

The supervisor then also recognizes this as a volatile situation and takes appropriate action.

On the other hand, the LED lock module 127 serves to check the remaining power of the power supply according to the standby power supply of the battery module 126.

The checked remaining amount information is transmitted to the monitor terminal 150 through the central management server 140.

Then the supervisor checks the state of the standby power supply, and recognizes this as a fluctuation situation and takes appropriate measures.

The communication module 128 functions to transmit event information generated in the collateral terminal 120 to the central management server 140 via the wireless communication network 170 or to interface with the central management server 140 so that the event information can be received.

In this way, due to the presence of the special key lock module 125, the battery module 126, and the LED lock module 127, a fluctuation symptom through a plurality of sensors is not detected, The state of the collateral can be monitored continuously, and the collateral can be prevented from being lost or the like.

However, the above-mentioned prior art is not suitable for monitoring the collateral for a long period of time because the power is consumed in a relatively short period because the power is wasted when operating as a battery.

Therefore, even if the battery operates, it is necessary to provide a collateral terminal which is designed with low power and can be used for a long time.

Also, conventionally, when the debtor has intentionally damaged the collateral terminal and made it impossible to communicate and monitor it, it is difficult to recognize it, and it is difficult to appropriately cope with it because it is detected after a long time.

Korea Patent Registration No. 10-1260481 (2014.04.26)

The above-mentioned collateral terminal mentioned above has a disadvantage that it can not be used for a long time when it operates as a battery, and when a communication module, a power supply and a standby power are intentionally damaged, it is difficult for the monitor to recognize and cope with it.

Accordingly, it is an object of the present invention to provide a system and method capable of appropriately coping with a communication module of a collateral terminal when the communication module of the collateral terminal is designed to provide a low-power collateral terminal.

The features of the present invention to achieve the objects of the present invention and to carry out the functions of the present invention described below are as follows.

According to an embodiment of the present invention,

Collateral to which the debtor is provided as collateral to the creditor in the case of a secured loan; Wherein the event information includes at least one of a first occurrence value of the fluctuation symptom and a time lapse after the first occurrence value of the fluctuation symptom, And a change occurrence value according to the change occurrence value;

A central management server that receives and manages event information generated in a collateral terminal through a wired and wireless communication network; And a monitor terminal for checking the status of the collateral according to the event information and / or the degree of danger sent from the central management server through a wired or wireless communication network,

The collateral terminal is designed with low power and transmits abnormality data periodically to the central management server. A collateral monitoring system including the low-power collateral terminal is provided.

Implementation of low power is a main function that can reduce the maintenance cost by increasing the period of operation without replacing the power source when the collateral terminal operates as a battery. In addition, if the debtor has intentionally damaged the collateral handset to make communication and monitoring impossible, the supervisor will be able to cope with it properly.

According to the present invention, there is provided a collateral monitoring system comprising:

According to the present invention, since the collateral terminal installed in the collateral and the central management server are provided, it is possible to immediately check the change of the collateral without visiting even by visiting the collateral terminal, In particular, the low-power consumption of a collateral terminal provides long-term maintenance of battery life.

Therefore, it is possible to prevent the outflow of the collateral which may be destroyed in advance, to prevent the disadvantage of the contract due to the collapse of the collateral, and to maintain the right of priority payment of the collateral, and even if the collateral terminal is intentionally damaged, And it is possible to prevent damages due to insolvency management and to reduce the management time and cost of the collateral because the on-site manager (watcher) does not have to visit from time to time. Also, And provides an economical benefit of implementing low power and reducing maintenance cost.

1 is a view showing a monitoring form (management) of a general collateral.
FIG. 2 is an exemplary view of a conventional security monitoring system 100.
3 is a detailed block diagram of a conventional security terminal.
4 is a flowchart illustrating a method for monitoring a collateral (S100) using a conventional wired / wireless communication network 170 according to the related art.
FIG. 5 is a flowchart illustrating a step S120 according to the related art in more detail.
6 is a detailed configuration diagram of a security terminal according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, so that those skilled in the art can easily carry out the present invention. In the drawings, like reference numerals refer to the same or similar functions throughout the several views.

FIG. 2 is an exemplary view of a conventional security monitoring system 100.

2, the conventional security monitoring system 100 includes a collateral 110, a collateral terminal 120, a GPS 130, a central management server 140, a monitor / creditor terminal 150 160, and a wired and wireless communication network 170.

First, the collateral 110 according to the prior art refers to an industrial or property having an industrial value, such as a machine, a machine, a computer, an electronic device, or a living apparatus.

The collateral 110 is provided by the creditor financial institution as a collateral loan, and in return, the debtor is provided to the financial institution during the collateral loan period.

Next, the collateral terminal 120 according to the related art is installed in the collateral 110 to detect a change in the collateral.

Here, the fluctuation symptom refers to at least one of movement, vibration, position, power use and heat of the collateral 110.

For example, when the collateral 110 moves, the collateral terminal 120 senses the movement as a variation sign, and performs the tracking of the position of the collateral 110 at the same time.

Also, when the collateral 110 vibrates, the collateral terminal 120 senses the collision as a variation sign, and simultaneously performs the tracking of the position of the collateral 110.

When the position of the collateral 110 is shifted, the collateral terminal 120 senses the positional change as a variation sign, and performs tracking of the position of the collateral 110 at the same time.

Also, if there is no use of electric power by checking the use of electric power of the collateral 110, the collateral terminal 120 senses it as a fluctuation symptom, and simultaneously performs the position tracking of the collateral.

Further, if there is any heat in the collateral, the collateral terminal 120 senses the occurrence of heat as a fluctuation sign, and simultaneously performs the position tracking of the collateral 110. [

In the case of detecting heat, it is limited to the case where the collateral 110 is a mechanical facility.

In this manner, a plurality of jobs can detect a fluctuation symptom simultaneously or individually.

If it is detected as such a fluctuation symptom, the collateral terminal 120 according to the related art generates different event information according to the fluctuation symptom.

At this time, the event information includes the occurrence value of the fluctuation symptom and the occurrence occurrence value of the occurrence value over time after the generation.

For example, a first occurrence value in which a motion is generated in response to a motion variation indication is generated, and event information is generated by periodically or real-time checking a motion variation occurrence value over time after the occurrence value is generated .

In addition, the first occurrence value in which the position movement is generated in the event of the position movement change is generated, and the position movement change occurrence value in accordance with the passage of time is periodically or real-time checked after the occurrence value is generated to generate the event information .

Other elements generate the first occurrence value and the corresponding occurrence value as in the above example.

Here, at least one or more fluctuation indications of the movement, vibration, position, and power use of the collateral 110 are detected using a plurality of detection sensors.

Accordingly, the collateral terminal 120 according to the related art has a plurality of detection sensor modules.

Detection of a fluctuation symptom using the plurality of detection sensor modules will be described later in more detail with reference to FIG.

Next, the GPS 130 according to the related art confirms the position information of the collateral 110 to check the position and the movement of the collateral 110 among the change indications described above, and provides it to the collateral terminal 120 do.

Of course, the location information of the collateral 110 is provided at the request of the collateral terminal 120.

The GPS 130 does not provide location information to the collateral terminal 120 but may provide location information at the request of the central management server 140 or the monitor terminal 150 to be described later.

As described above, the GPS 130 according to the related art can be usefully used for detecting a change in signs according to the position information of the collateral 110.

Next, the central management server 140 according to the related art receives and manages event information generated in the collateral terminal 120 through the wired and wireless communication network 170, and transmits the event information to the monitor terminal 150 It serves to provide.

In addition, the central management server 140 checks the first occurrence value and the variation occurrence value of the event information provided from the collateral terminal 120, and gives a risk degree.

For example, if the occurrence value of the change over time after the occurrence of the first occurrence value for the movement is changed from time to time, the degree of risk such as very serious, somewhat serious, serious, have.

This risk level is also immediately provided to the monitor terminal 150.

In addition, other elements (vibration, position, power use, heat, etc.) may be provided to the monitor terminal 150 in accordance with the above-described principle.

The central management server 140 may manage the event information and / or the degree of danger generated by the respective collateral terminals 120 when a plurality of the collateral 110, the collateral terminal 120 and the monitor terminal 150 are provided. The identification information is managed to provide the identification information to the monitor terminal 150 and the identification information of the collateral terminal 120 or the monitor terminal 150 can be identified through the identification information and the corresponding data can be transmitted.

Since the utilization of such identification information is generally known, a more detailed description will be omitted.

The monitor terminal 150 according to the related art checks the status of the collateral 110 according to the event information and the degree of danger sent from the central management server 140 through the wired and wireless communication network 170 .

If the event information and the degree of risk are immediately checked without visiting the fluctuation state of the collateral 110, the credit information is notified to the creditor (financial institution or the creditor terminal 160) and immediately responded, It is possible to prevent the destruction of the collateral 110 and to prevent the loss of the collateral 110 in advance.

The wireless communication network 170 according to the related art can smoothly transmit and receive wireless data between the collateral terminal 120 and the central management server 140 and between the collateral terminal 120 and the monitor terminal 150 Wireless technology.

The wireless communication network 170 is preferably a wibro, 2G, or 3G mobile communication network. Accordingly, the security terminal 120 connected to the central management server 140 and the monitor terminal 150 may include a wireless communication interface module capable of communicating with each other.

The monitor terminal 150 and the creditor terminal 160 may be a wired communication network 170 instead of the wireless communication network 170. In this case, the monitor terminal 150 and the creditor terminal 160 may be PCs.

3 is a block diagram showing a configuration of a collateral terminal 120 according to the related art in more detail.

3, the conventional collateral terminal 120 includes a gyro sensor module 121, a vibration sensor module 122, a position tracking sensor module 123, a power sensor module 124, and a control module 129, .

The gyro sensor module 121 according to the related art interfaces between the gyro sensor provided in the collateral terminal 120 and the control module 129. The gyro sensor module 121 measures the movement of the collateral 110 using the gyro sensor do.

Such a gyro sensor senses the angular velocity to measure the movement of the collateral 110.

It can be seen that the movement of the collateral 110 is in progress or the movement of the collateral 110 is changed at any time.

The vibration sensor module 122 according to the related art is a module for interfacing between the vibration sensor provided in the collateral terminal 120 and the control module 129 and measures a vibration generated in the collateral 110 using a vibration sensor .

The vibration sensor is also referred to as a sound sensor or an acceleration sensor.

If vibration continues or changes in size from time to time, it can be seen that the collateral 110 is moving to another location.

The location tracking sensor module 123 according to the related art is a module for interfacing between the location tracking sensor provided in the collateral terminal 120 and the control module 129. The location tracking sensor module 123 detects the location of the collateral terminal 120 Track movement.

In order to track the location and movement of the collateral terminal 120, the location tracking sensor communicates with the GPS to acquire and process the location information from the GPS.

If the location information is changed frequently, it can be known that the collateral 110 is moving when compared with the first location information.

The power sensor module 124 according to the related art is a module for interfacing between the power sensor provided in the collateral terminal 120 and the control module 129. The power sensor module 124 detects the presence or absence of power used in the collateral 110 .

For example, if the collateral 110 is still being used, the normal amount of power will be checked, and if not, the abnormal amount of power will be checked.

The conventional thermal measurement sensor module 129a is a module for interfacing between the thermal measurement sensor provided in the collateral terminal 120 and the control module 129 and measures the heat generated from the collateral using a thermal measurement sensor .

Such thermal sensing is suitable for particular collateral 120, e.g., a collateral 120 that normally generates heat.

The control module 129 according to the related art controls the data flow between the gyro sensor module 121, the vibration sensor module 122, the position tracking sensor module 123, the power sensor module 124 and the thermal sensor module 129a As well as controlling the flow of data between the special key lock module 125, the battery module 126, the LED lock module 127 and the communication module 128, which will be described below.

As described above, by monitoring various signs of the collateral 110 by using various sensors, the creditor can immediately deal with the fluctuation situation in advance.

However, the conventional collateral terminal 120 includes the gyro sensor module 121, the vibration sensor module 122, the position tracking sensor module 123, the power sensor module 124, the control module 129, In addition to the module 129a, a special key lock module 125, a battery module 126, an LED lock module 127, and a communication module 128 may be further provided.

Thus, each of the further modules will be described.

The special key lock module 125 according to the related art is installed at the lower end of the collateral terminal 120 and receives a release command through the special key to receive the special key lock module 125 and the collateral (110).

The special key lock module 125 prevents the collateral terminal 120 installed on the collateral 110 from being separated so that the inherent function of the collateral terminal 120 described above is maintained.

This special key lock module 125 is a module required under the assumption of the worst case.

Next, the battery module 126 according to the prior art continuously supplies the standby power to each module through the charged power when the power is not supplied to each module.

At this time, if the power is not supplied, the debtor must forcibly cut off the power supply or prevent the power supply from being cut off due to the power failure.

Accordingly, each module operates according to the standby power source, so that it is possible to continuously detect a fluctuation symptom.

And informs the central management server (140) and / or the monitor terminal (150) as event information.

The supervisor then also recognizes this as a volatile situation and takes appropriate action.

On the other hand, the LED lock module 127 according to the related art functions to check the remaining amount of the power source according to the standby power supply of the battery module 126.

The checked remaining amount information is transmitted to the monitor terminal 150 through the central management server 140. Then the supervisor checks the state of the standby power supply, and recognizes this as a fluctuation situation and takes appropriate measures.

The communication module 128 according to the related art functions to transmit event information generated in the collateral terminal 120 to the central management server 140 via the wireless communication network 170 or to interface with the central management server 140 so that the event information can be received.

In this way, due to the presence of the special key lock module 125, the battery module 126, and the LED lock module 127, a fluctuation symptom through a plurality of sensors is not detected, The state of the collateral can be monitored continuously, and the collateral can be prevented from being lost or the like.

4 is a flowchart illustrating a method for monitoring a collateral (S100) using a conventional wired / wireless communication network 170 according to the related art.

As shown in FIG. 4, the method of monitoring a collateral using a wire / wireless communication network 170 according to the related art (S100) is a method in which a debtor (financial institution) (S110).

Thereafter, the method for monitoring a security in a conventional manner (S100) detects a change in the collateral 110 in the collateral terminal 120 installed in the collateral 110 (S120).

At this time, the method for monitoring the collateral (S100) can detect at least one or more variation signs of the movement, vibration, position, power use, and heat of the collateral 110 by using a plurality of detection sensors disposed in the collateral terminal 120 have.

The detected fluctuation indications are generated as respective event information.

Since the event information is fully described in FIG. 2, the description thereof will be omitted.

The security monitoring method S100 according to the related art then transmits the event information generated according to the detection of the fluctuation symptom of the collateral terminal 120 to the central management server 140 through the wireless communication network 170, (S130).

Herein, the reception is automatically performed according to the automatic detection of the collateral terminal 120.

The security monitoring method S100 according to the related art sends a change status of the collateral 110 to the monitor terminal 150 via the wireless communication network 170 according to the event information sent from the central management server 140 , The monitor terminal 150 checks the change status of the collateral 110 (S140).

In addition, the security monitoring method (S100) according to the related art can receive and check the danger level according to the event information together with the fluctuation according to the event information from the central management server 140 (S140).

Since the significance of the degree of danger is fully explained in Fig. 2, the description thereof is omitted.

The security monitoring method S100 according to the related art immediately informs the creditor terminal 160 via the wireless communication network 170 of the changed status checked in the monitor terminal 140 at step S150.

Accordingly, the creditor (financial institution) can immediately prevent the debtor's collateral 160 from being destroyed.

FIG. 5 is a flowchart illustrating a step S120 according to the related art in more detail.

5, in step S120 according to the related art, movement of the collateral 110 is measured using a gyro sensor among a plurality of sensors, vibration of the collateral 110 is measured using a vibration sensor, The position of the collateral 110 is tracked using a position-tracking sensor among the plurality of sensors (S121).

At this time, since the position tracking sensor is provided with the position information of the collateral 110 sent from the GPS, it can track the position of the collateral 110. [

Also, in step S120 according to the related art, the presence or absence of power use of the collateral 110 is measured using a power sensor among the plurality of sensors, and the presence or absence of heat generation of the collateral 110 And strength (S121).

In this manner, the measured or tracked change indication is generated as event information and sent to the central management server 140 for use.

The event information is described in Fig.

In step S120 according to the related art, the collateral terminal 120 may be disassembled from the collateral 110 by unlocking a special key inserted into the special key lock module 125 installed in the collateral terminal 120 S122).

This disassembly process can prevent the collateral terminal 120 from being separated from the collateral 110 by allowing the collateral terminal 120 to be disassembled only when only the special key is used.

This is to maintain the detection of the fluctuation symptom of the collateral terminal 120.

If the power supply for performing the respective steps is not performed in step S120 according to the related art, the power is supplied to the collateral terminal 150 through the battery (S123).

As a result, it is possible to continuously detect the fluctuation symptom according to the power source.

In step S120 according to the related art, when power is supplied from the battery in step S123, the battery residual amount information checked in the power source is transmitted to the monitor terminal 150 via the central management server 140 (S124).

By checking the battery remaining amount information, the connection state between the collateral terminal 150 and the collateral 110 can be checked to prevent a situation such as a loss of the collateral 110 or the like.

 6 is a detailed configuration diagram of a security terminal according to an embodiment of the present invention.

Referring to FIG. 6, FIG. 6 is a diagram further illustrating modules for implementing low power and modules for periodically transmitting abnormality data in the construction of the collateral terminal 120 according to the prior art of FIG.

In the case where the collateral is installed in a place where no electric power is supplied, the collateral terminal according to the present invention may be forced to use the battery.

In this case, the life of the battery affects the number of maintenance.

Therefore, in order to extend the life of the battery, it is required that the collateral terminal be operated in a manner of low power design and power saving.

In the present invention, a change in vibration and angular velocity caused by daily life is defined as life oscillation.

The control module is able to input the variation range of the vibration and angular velocity of the vibration sensor module and the gyro sensor module according to daily life. Therefore, although the basic setting is performed in the factory where the life vibration setting module 610 is required and the collateral terminal is manufactured, according to the installation environment installed, the life vibration is detected for a certain period of time during installation, .

The installer can set it through the control module of the collateral terminal via the wired and wireless communication network at the central management server, or can input it directly to the collateral terminal.

Detection of vibration sensor and gyro sensor by daily life is only log data and there is no operation by generating an event separately.

The log data is stored in the log data storage module 620 of the collateral terminal, and is transmitted to the central management server when the communication module operates, such as when an event occurs or when there is periodic abnormality data transmission.

However, the sensing of the sensor that deviates from everyday life is judged as an event according to the duration, and the event information is transmitted to the server through the communication module so that the event of the collateral is detected by the central management server.

Accordingly, since the low-voltage collateral terminal records only the log data with respect to the life oscillation, it does not need to operate the communication module that consumes a lot of power, thereby realizing low power.

In the present invention, the detection period and the sleep period are set, but the detection period setting module 630 and the sleep period setting module 640 are used. When the control module is activated according to the detection period and is in the sleep period according to the sleep period So that low power is realized.

The settings of the detection period setting module 630 and the sleep period setting module 640 are the same as those of the vital vibration setting module 610.

That is, it can be set in the factory, and it can be set through the control module via the communication module in the central management server.

In the present invention, in order to realize a low power, the control module is operated not at all times but at intervals of 24 hours, and when it is not a detection period, it is dormant.

In one embodiment, if the sensing period is set to 10 seconds, and the dormancy period is set to 20 seconds, the control module operates the sensor for sensing for 10 seconds and rests the sensor operation for sensing for 20 seconds.

In order to generate an event, it is important how long the detection of life vibration is continued, and a module capable of setting it is necessary. A duration setting module 650 is provided to set the duration.

In this embodiment, if the duration is set to 20 seconds and the detection period is set to 10 seconds and the dormancy period is set to 20 seconds, the control module senses the vibration over life vibrations for 10 seconds, The event is not generated.

However, in this case, when the control module senses the vibration of the life vibration for 10 seconds and then the vibration of the life vibration for 10 seconds after the 20 seconds of dormancy, the event is generated. That is, when the vibration of the life oscillation is continued for 20 seconds or more, an event occurs.

In the present invention, a low power chip is used as another means for realizing low power. The low-power chip is designed to use one-hundredth the power of an ARM chip used in mobile phones. Therefore, the battery capacity of the mobile phone can be operated for 300 days to 600 days or more.

In addition, the programming language being hired and the low-power chip minimized the time and step by which the program was designed and run as an assembly.

Usually ARM uses C language and JAVA to increase the number of steps compared to assembly, so it is not suitable for low power.

In another aspect of the present invention, the notification period setting module 660 is configured so that even if the debtor intentionally damages the communication module or damages the power source and the battery module, the central management server can recognize the danger and inform the monitor of the danger level .

For example, if a collateral terminal sends data to the central management server every three hours (set by the notification period setting module), if the collateral terminal does not send such abnormal data, The central management server will check for the abnormality of the collateral terminal and inform the supervisor of the degree of danger.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments. It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is to be understood, therefore, that the embodiments described above are to be considered in all respects as illustrative and not restrictive.

The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

100: Mortgage monitoring system
110: Collateral
120: Handset terminal
121: Gyro sensor module
122: Vibration sensor module
123: Positioning sensor module
124: Power sensor module
125: Special key lock module
126: Battery module
127: LED lock module
128: Communication module
129: Control module
130:
140: Central Management Server
150: Monitor terminal
160: creditor terminal
170: wired and wireless communication network
610: Life vibration setting module
620: Log data storage module
630: Detection period setting module
640: Sleeping Cycle Setting Module
650: Duration setting module
660: Notification cycle setting module

Claims (6)

In a collateral monitoring system,
A mortgage (110) in which the debtor is provided as collateral to the creditor in a secured loan;
Wherein the event information includes at least one of a first occurrence value of the fluctuation symptom and a time lapse after the first occurrence value of the fluctuation symptom, As shown in FIG.
In the case of life vibration that does not maintain a constant duration, it is recorded only in the log data. However, it does not use the communication module to prevent power consumption due to communication, and the vibration sensor module and the gyro A vital vibration setting module 610 for setting a variation range of the vibration and the angular velocity of the sensor module,
The log data storage module 620 and
The detection period setting module 630
The sleep period setting module 640
A security terminal (120) further comprising a duration setting module (650) which can set how long the detection of life vibrations should be continued to generate an event;
A case where at least one of movement, power use, heat generation, and vibration occurrence of the collateral among the event information provided through the wired and wireless communication networks is detected as the initial occurrence value, A central management server (140) for managing the degree of risk for the collateral by using the variation occurrence value when the number of fluctuations is further detected;
And a monitor terminal (150) for checking the change status of the collateral according to the degree of risk of event information sent from the central management server through the wired or wireless communication network,
The collateral terminal is designed with low power,
And a battery module for receiving standby power when the power of the collateral terminal is cut off. The battery module further includes an LED check module, and the remaining amount information checked by the LED check module is transmitted to the monitor terminal Lt; / RTI >
And a notification period setting module (660) for periodically transmitting abnormality data to the central management server. delete delete delete delete delete

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