KR101444175B1 - System for managing noise in apartment house and operting method thereof - Google Patents

Abstract

The present invention relates to a noise managing system and an operating method thereof, capable of detecting a household making a noise between floors by monitoring noises and vibrations generated in an apartment house. The noise managing system according to the present invention can comprise; one or more monitoring devices which are installed inside the each household and measure noises and vibrations in a household in real time; and a noise managing device which detects a household making a noise from noise and vibration values received from the monitoring device. The generation of a noise of the household making the noise is controlled and is handled through the present invention. Therefore, a pleasant residential environment is provided to households in the apartment house, and a conflict cause surrounding a noise between the households is resolved. Moreover, a quarrel and a dispute between the households are resolved.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a noise management system in a multi-

The present invention relates to a noise management system and a method of operating the same in a multi-family house. More specifically, the present invention monitors noise and vibration generated in a multi-family house to determine a generation causing noise, And a method of operating the noise management system.

Interlayer noise refers to the noise pollution that occurs mainly in multi-family houses or apartments. Specifically, the interlayer noise is a generic term for toilet water, floor impact sound, piano sound, audio sound, conversation sound, TV sound, etc. In the past, Problems are emerging.

As with other noise pollution, interlayer noise has a negative impact on the mental and physical health of the members of each generation. This may lead to social problems such as complaints and many problems among neighboring residents.

In particular, the floor impact sound (ie, solid sound transmission) caused by the direct impact on the concrete surface, such as the sound of beating children and moving or falling objects, In terms of having, the stratification due to the interlayer noise can easily occur.

However, in the case of apartment houses in Korea, the floor is mostly composed of the slab layer, the insulation layer on the upper slab, the lightweight concrete or foam concrete layer, the heating coil layer and the finishing mortar layer. The foamed polystyrene is used as a foamed polystyrene having an effect of blocking the floor impact sound of the floor, so that the construction is performed without using a separate noise shielding material.

To solve these problems, construction companies have attempted to increase the thickness of the floor concrete between generations from 120 mm to 180 mm or 210 mm, or to modify the structure and material of the flooring so as to absorb the noise and vibration between the floors However, this is causing the increase of building load and construction cost. In addition, although the above problems are reduced, the interlayer noise can be reduced by the above-described method in a new apartment house, but the existing house still has a problem of interlayer noise. In addition, since the resolution of the concrete thickness may cause a dispute of the interlayer noise depending on the degree of the noise of the residents, it is necessary to understand and understand the noise reduction among the residents by the information of the quantitative noise figure.

Therefore, considering the reality that it is difficult to completely solve such a noise problem, a technology that can solve the conflict around the noise problem in the apartment house is required.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a technique for monitoring noise and vibration generated in a multi-family house to identify noise generation and noise generation.

According to an embodiment of the present invention, a noise management system for a plurality of households constituting a multi-family house is disclosed. Wherein the noise management system comprises at least one monitoring device installed in each generation to measure noise and vibration in the generation in real time; And a noise management apparatus for determining a noise generation generation that generates noise from noise values and vibration values received from the monitoring apparatus, wherein the noise management apparatus includes an interface for receiving the noise value and the vibration value from the monitoring apparatus, module; A database for storing the noise value and the vibration value, the information including a positional relationship between a plurality of generations constituting the apartment; And comparing the noise value with a predetermined noise threshold value to detect a noise generation generation having a noise value exceeding the noise threshold value and comparing the vibration value measured at the noise generation generation with a predetermined vibration threshold value, And a control module that determines whether or not noise is generated and determines a noise-induced generation from the noise generation generation based on information on the positional relationship between the generations when it is determined that the interlayer noise is generated.

Preferably, the monitoring device comprises at least one noise measurement sensor for measuring the noise in the generation to generate the noise value; At least one vibration measurement sensor for measuring vibrations within the generation to produce the vibration value, the vibration measurement sensor being located within the generation to measure vibrations transmitted from top to bottom; And a gateway for configuring a home network or a smart grid communication network including the noise measurement sensor and the vibration measurement sensor within each generation and communicating with the noise management device.

According to an embodiment of the present invention, a method of operating a noise management system for a plurality of households constituting a multi-family house is disclosed. Generating a noise value by measuring noise in the generation in real time; Generating vibration values by measuring vibrations in the generation in real time; Comparing the noise value with a predetermined noise threshold value to detect a noise generation generation having a noise value exceeding the noise threshold value; Comparing a vibration value measured in the noise generation generation with a predetermined vibration threshold value to determine whether or not an interlayer noise is generated; And determining a noise-induced generation from the noise generation generation based on information on a positional relationship between the generations when it is determined that the interlayer noise is generated.

According to an embodiment of the present invention, a computer readable medium is provided that includes computer instructions for performing a method of operating a noise management system for a plurality of households that make up a house.

The present invention monitors the noise and vibration occurring in each household in a common house in real time to determine whether noise is generated and determine the generation that causes noise. As a result, it is possible to provide a comfortable living environment to the households in the apartment house while solving the causes of the conflicts among the households, You can resolve conflicts and conflicts between the two.

BRIEF DESCRIPTION OF THE DRAWINGS A brief description of each drawing is provided to more fully understand the drawings recited in the description of the invention.
1 illustrates a noise management system according to an embodiment of the present invention.
2 shows a monitoring apparatus according to an embodiment of the present invention.
3 illustrates a noise management apparatus according to an embodiment of the present invention.
FIG. 4 illustrates a method of operating a noise management system according to an embodiment of the present invention.
Fig. 5 is a diagram exemplarily showing a multi-family house.
Figure 6 illustrates some of the houses shown in Figure 5.

Hereinafter, embodiments according to the present invention will be described with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In addition, embodiments of the present invention will be described below, but the technical idea of the present invention is not limited thereto and can be variously modified by those skilled in the art.

Throughout the specification, when a part is referred to as being "connected" to another part, it includes not only "directly connected" but also "indirectly connected" . Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

As used in this application, the terms "component,""module," and "system" are intended to refer to computer-related entities such as hardware, firmware, a combination of hardware and software, . For example, a module may be, but is not limited to, a process running on a processor, a processor, an object, an executable, an execution thread, a program, and / or a computer. For example, both an application running on a computing device and a computing device may be modules. One or more modules may reside within a process and / or thread of execution, and the modules may be localized on one computer and / or distributed among two or more computers. Such modules may also be executed from various computer readable media in which various data structures are stored. Modules may include, for example, signals having one or more data packets (e.g., data from a local system, data from one module interacting with another module in a distributed system, and / Lt; RTI ID = 0.0 > and / or < / RTI >

1 illustrates a noise management system 100 according to an embodiment of the present invention.

Referring to FIG. 1, the noise management system 100 is for managing noise in a house, and may include at least one monitoring device 110 and a noise management device 120.

Here, a multi-family house consists of a plurality of households, each of which has a structure in which a plurality of households can use the whole or a part of a building's walls, corridors, stairs, Apartments, tenement houses, multi-family houses, and the like.

The monitoring device 110 may be installed in each household to generate noise values and vibration values by measuring noise and vibration in real time in real time, and may transmit noise values and vibration values to the noise management device 120. One monitoring device 110 may correspond to one generation and may constitute a home network or a smart grid communication network within each household.

The noise management device 120 is located at a remote location that can be connected to at least one monitoring device 110 by a wired / wireless network. The noise management device 120 determines a noise generation generation that generates noise from the noise value and vibration value transmitted from the monitoring device 110 , And can transmit a noise warning signal.

2 shows a monitoring apparatus 200 according to an embodiment of the present invention.

Referring to FIGS. 1 and 2, a monitoring apparatus 200 is installed in each generation and may include a noise measurement sensor 210, a vibration measurement sensor 220, and a gateway 230.

The noise measurement sensor 210 can generate a noise value by measuring noise within the generation. At least one noise measurement sensor 210 may be installed in each household within the apartment complex and may be located at a location suitable for measuring noise within the household.

The vibration measurement sensor 220 can measure vibration within a generation to generate vibration values. The vibration measurement sensor 220 is for measuring vibration occurring in a household, and may include, for example, an optical fiber sensor, a piezoelectric vibration sensor, an acceleration sensor, and the like. At least one vibration measurement sensor 220 may be installed in each household within the apartment complex, and may be located at a suitable location to detect interlayer noise, among others. Preferably, it may be located at a location capable of measuring vibrations transmitted in a top-down direction to detect interlayer noise caused by a floor impact sound. For example, such a location may be a ceiling within a household, a floor, a wall between a generation and a generation, and the like.

In one embodiment, a plurality of vibration measurement sensors and / or a plurality of noise measurement sensors may be installed within one generation, in which case, for example, the living room and the entrance, It is possible to distinguish whether it is self-noise or external noise.

In one embodiment, the noise measurement sensor and the vibration measurement sensor may be combined and installed at the same location.

The gateway 230 may be installed in each household and may form a home network or a smart grid communication network within each household together with the noise measurement sensor 210 and the vibration measurement sensor 220. Such home network or smart grid communication network can process various information communication devices within the household (for example, PC, PDA, mobile phone, web pad, smart TV set-top box, PMP, IP cam, wall pad) (For example, devices that have communication and control functions in existing home appliances such as refrigerators, washing machines, air conditioners, boilers, and microwave ovens), intelligent sensors (for example, door sensors, (For example, gas sensors, fire smoke sensors, glass window break sensors, heat sensors, biometric sensors, etc.), intelligent controllers (for example, various controllable devices such as gas valves, electric curtains, Can be connected.

The gateway 230 may receive noise values and vibration values from the noise measurement sensor 210 and the vibration measurement sensor 220 and may transmit the noise values and the vibration values to the noise management apparatus 120, And can transmit various signals to various information communication devices constituting a home network or a smart grid communication network. A variety of wire and wireless communication standards and techniques available in the art may be used for such communications of the gateway 230.

FIG. 3 shows a noise management apparatus 120 according to an embodiment of the present invention.

1 to 3, the noise management apparatus 120 may include an interface module 310, a database 320, and a control module 330.

The interface module 310 may communicate with the gateways 230 of the monitoring devices 110 within a plurality of generations.

Specifically, the interface module 310 receives the noise value and the vibration value from the gateway 230, and provides the noise value and the vibration value to the control module 330. As described below, the control module 330 may determine the noise generation and the noise generation generation from the noise values and vibration values received from the interface module 310. In addition, the interface module 310 may transmit the noise warning signal to the noise-induced generation (or the noise-induced generation monitoring device 110) according to the operation of the control module 330. Here, the noise warning signal is a signal notifying that noise is generated by the noise generation generation. The gateway 230 included in the monitoring device 110 of the noise-inducing household receives the noise warning signal and then transmits the noise warning signal to the home network or the information communication device constituting the smart grid communication network (e.g., TV set-top box, etc.).

In addition, the interface module 310 may receive the information request signal through an arbitrary generation (or a monitoring device 110 of an arbitrary device) and provide the information request signal to the control module 330. The interface module 310 may transmit the noise value and the vibration value of each generation according to the operation of the control module 330 in response to the reception of the information request signal. After receiving the noise value and the vibration value of each generation, the gateway 230 included in the monitoring device 110 of any generation generates a home network or an information communication device (for example, A wall pad, a mobile phone, a smart TV set-top box, etc.). In one embodiment, the noise values and the vibration values transmitted to at least one of the information communication devices are such that the current value of each of the noise value and the vibration value, the average value, the peak value, the noise value and the vibration value within a predetermined period exceed a certain value Number of times, and value relating to time. In one embodiment, the noise values and vibration values transmitted to any generation may be defined by the noise values and vibration values of the generations associated with any and all generations, wherein the generations associated with any generation are random And can be influenced by noise and can be determined from the information on the positional relationship between the generations.

The database 320 may store noise values and vibration values of each generation received by the interface module 310. Also, the database 320 may include information on the positional relationships among the generations constituting the apartment house. The information on the positional relationship between the generations is related to the location or connection between any household and other households that may be affected by noise from any of the households based on the physical proximity and directionality between the plurality of households constituting the apartment house. Information. Information about the location relationship between generations can be used to determine generations associated with any generation, or to determine noise-driven generations. According to an embodiment, the database 320 may store both the noise values and the vibration values of each generation received by the interface module 310, or may store noise values and vibration values that exceed a certain reference value, respectively.

The control module 330 can determine the generation of the interlayer noise and the noise generation generation by using information on the noise value, the vibration value, and the positional relationship between the generations.

Specifically, the control module 330 may compare the noise value measured within the household with a predetermined noise threshold to detect a noise generation generation having a noise value exceeding the noise threshold. Noise generated in the generation of noise is the noise generated in the generation of the noise, the noise propagated from the neighboring generation (for example, the interlayer noise) Lt; / RTI >

When a noise generation generation is detected, the control module 330 may compare the vibration value measured by the vibration measurement sensor 220 of the noise generation generation with a predetermined vibration threshold value to determine whether or not the interlayer noise is generated. The vibration value measured by the vibration measurement sensor 220 is used to determine whether or not such a noise corresponds to the inter-layer noise propagated from the upper generation even if noise exceeding a predetermined noise threshold occurs in the generation generation of the noise will be. If the measured vibration value exceeds a predetermined vibration threshold value, it can be determined that the inter-layer noise occurs. Conversely, if the measured vibration value does not exceed the predetermined vibration threshold value, it can be determined that no inter-layer noise occurs. In this case, the noise in the noise generation generation may have occurred in the noise generation generation itself, or may be generated in the next generation or lower generation of the noise generation generation. However, considering that the noise generated from the next generation or below generation is difficult to propagate to the generation of noise in the structure of the apartment house, in the present invention, the noise in the generation of noise can be estimated as self noise in the generation of noise .

The noise value and the vibration value compared with the noise threshold value and the vibration threshold value by the control module 330 are determined by the noise value measured by the noise measurement sensor 210 and the vibration value measured by the vibration measurement sensor 220, The current value, the average value within a predetermined period, the peak value, the number of times that the noise value and the vibration value each exceed a certain value, or a value related to time.

If it is determined that the interlayer noise is generated, the control module 330 can determine the noise generation generation causing the interlayer noise to the noise generation generation. This determination may be based on the positional relationships among the generations included in the database 320. [ That is, based on the positional relationship, the generation that can induce the interlayer noise in the noise generation generation can be determined as the noise generation generation. Depending on the embodiment, the noise-induced generation may be determined taking into account not only the positional relationship but also the noise measured in the adjacent generation. Further, when there are a plurality of generations that can cause the inter-layer noise, the noise-induced generation can be determined by taking information on the position of the vibration measurement sensor 220 into consideration.

Conversely, when it is determined that no inter-layer noise is generated, the control module 330 can determine the noise generation generation as a noise generation generation that generates self noise. As mentioned above, considering that the noise generated from the next generation or below generation is not spread to the generation of noise in the structure of the apartment house, the noise in the noise generation generation is not the noise generated from the adjacent generation, It is judged as the own noise in the generation generation.

Once the noise-driven generation has been determined, the control module 330 may send a noise warning signal to the noise-generating household (or monitoring device 110 of the noise-generating household) via the interface module 310. Here, the noise warning signal is a signal for notifying that noise is generated by the noise generation generation. The gateway 230 included in the monitoring device 110 of the noise-inducing household receives the noise warning signal and then transmits the noise warning signal to the home network or the information communication device constituting the smart grid communication network (e.g., TV set-top box, etc.).

Transmission of the noise warning signal may be different depending on whether the noise generation generation is a generation causing interlayer noise or a generation causing self noise. For example, if the noise generation generation and the noise generation generation are the same (i.e., the self noise generation occurs), the control module 330 can compare the noise value of the noise generation generation with the second noise threshold. As a result of the comparison, if the noise value of the noise generation generation exceeds the second noise threshold value, the noise notification signal may be transmitted to the noise generation generation (or monitoring device 110 of the noise generation generation) through the interface module 310 . Here, the second noise threshold value may be a value larger than the noise threshold value for determining the noise generation generation.

In the present invention, at least one of the noise threshold and the vibration threshold used by the control module 330 may be a fixed value, a variable value or a plurality of values (e.g., a first noise threshold and a second noise Threshold). In particular, at least one of the noise threshold and the vibration threshold used by the control module 330 may be variable over time. For example, different values can be applied depending on the morning and the night. Also, at least one of the noise threshold value and the vibration threshold value may be applied to different generations. This can be determined in consideration of the environment inside and outside the apartment, and behavior patterns of the members of each household.

In one embodiment, the control module 330 responds to the information request signal received from any generation (or monitoring device 110 of any device) via the interface module 310 to determine the noise value and vibration value To any generation (or any generation of monitoring devices 110). After receiving the noise value and the vibration value of each generation, the gateway 230 included in the monitoring device 110 of any generation generates a home network or an information communication device (for example, A wall pad, a mobile phone, a smart TV set-top box, etc.). According to an embodiment, the noise value and the vibration value transmitted to at least one of the information communication equipments include a current value of the noise value and the vibration value, an average value within a predetermined period, a peak value, a noise value and a vibration value exceeding a certain value Number of times, and value relating to time.

In one embodiment, the noise values and vibration values transmitted to any generation by the control module 330 are limited to noise values and vibration values of at least one of the generations and the generations associated with any of the generations Where the generations associated with any generation can be determined from information about the location relationship between generations as generations that can be affected by noise and adjacent to any generation.

In one embodiment, the control module 330 may generate noise statistics data of the apartment house on the noise values and vibration values stored in the database 320. [ The noise statistics data may be, for example, daily, weekly or monthly statistics. Additionally, the control module 330 may generate a noise map indicating the degree of noise generated in the apartment house from the noise statistics data. According to an embodiment, the control module 330 may transmit noise statistical data and / or noise maps to any generation (or any generation of monitoring devices 110) via the interface module 310.

4 illustrates a method 400 of operation of the noise management system 100 in accordance with an embodiment of the present invention.

Referring to Figures 1-4, in step 410, the noise management system 100 may measure noise within a generation and generate a noise value. The noise measurement sensor 210 used in step 410 may be installed in at least one of each generation within the apartment house and may be located at a suitable location to measure noise within the household.

In step 420, the noise management system 100 may measure vibrations within the generation to produce vibration values. The vibration measured by the vibration measurement sensor 220 may be a vibration transmitted from the top to the bottom so that it can be used to detect the interlayer noise. In FIG. 4, step 420 is shown to be performed after step 410, but steps 410 and 420 may be performed substantially concurrently.

In step 430, the measured noise value may be compared to the predetermined noise threshold value in step 410 to detect a noise generation generation having a noise value that exceeds the noise threshold value. Noise generated in the generation of noise is the noise generated in the generation of the noise, the noise propagated from the neighboring generation (for example, the interlayer noise) Lt; / RTI >

In step 440, the vibration value measured in the noise generation generation among the vibration values measured in step 420 may be compared with a predetermined vibration threshold value to determine whether or not the interlayer noise is generated. If the measured vibration value exceeds a predetermined vibration threshold value, it can be determined that the inter-layer noise is generated. Conversely, if the measured vibration value does not exceed the predetermined vibration threshold value, it can not be judged that the interlayer noise does not occur. In this case, the noise in the noise generation generation may have occurred in the noise generation generation itself, or may be generated in the next generation or lower generation of the noise generation generation. However, considering that the noise generated from the next generation or below generation is difficult to propagate to the generation of noise in the structure of the apartment house, in the present invention, the noise in the generation of noise can be estimated as self noise in the generation of noise .

At step 450, a noise-induced generation may be determined from the noise generation generation. Specifically, if it is determined that interlayer noise is occurring (step 440), a noise-induced generation that generates interlayer noise in the generation of noise may be determined (step 450). The determination may be performed based on a positional relationship between generations. That is, based on the positional relationship, the generation that can induce the interlayer noise in the noise generation generation can be determined as the noise generation generation. Depending on the embodiment, the noise-induced generation may be determined taking into account not only the positional relationship but also the noise measured in the adjacent generation. Also, if there are multiple generations that can cause interstage noise, step 450 may be performed taking into account information about the location of the vibration measurement sensor. Conversely, if it is determined that no interstage noise occurs (step 440), the noise generation generation may be determined as the noise generation generation that generates its own noise (step 450). As mentioned above, considering that the noise generated from the next generation or below generation is not spread to the generation of noise in the structure of the apartment house, the noise in the noise generation generation is not the noise generated from the adjacent generation, It is judged to be self noise in generation generation

In steps 430 and 440, the noise values and vibration values that are compared to the noise threshold and vibration threshold are determined by the noise values measured by the noise measurement sensor 210 and the noise values measured by the vibration measurement sensor 220 A current value of each of the vibration values, an average value within a predetermined period, a peak value, a number of times that the noise value and the vibration value each exceed a certain value, and a value with respect to time.

Also, at least one of the noise threshold and the vibration threshold used in steps 430 and 440 may be a fixed value, a variable value or a plurality of values (e.g., a first noise threshold and a second threshold) Noise threshold). In particular, at least one of the noise threshold and the vibration threshold may be variable over time. For example, different values can be applied depending on the morning and the night. Also, at least one of the noise threshold value and the vibration threshold value may be applied to different generations. This can be determined in consideration of the environment inside and outside the apartment, and behavior patterns of the members of each household.

In one embodiment, the method 400 may further comprise storing the noise value and the vibration value. The stored noise values and vibration values may be used to perform steps 430 to 450, or may be used to generate noise statistics data for the apartment house. The noise statistics data may be, for example, daily, weekly or monthly statistics. Additionally, a noise map may be generated that represents the degree of noise generated in the apartment house from the noise statistics data. Depending on the embodiment, noise statistics data and / or noise maps may be transmitted to any generation (or any generation of monitoring devices 110).

In one embodiment, the method 400 may further comprise transmitting a noise caution signal to the noise inducing household. Here, the noise warning signal is a signal for notifying that noise is generated by the noise generation generation. The gateway 230 included in the monitoring device 110 of the noise-inducing household receives the noise warning signal and then transmits the noise warning signal to the home network or the information communication device constituting the smart grid communication network (e.g., TV set-top box, etc.).

Transmission of the noise warning signal may be different depending on whether the noise generation generation is a generation causing interlayer noise or a generation causing self noise. For example, if the noise generation generation and the noise generation generation are the same (i.e., when self noise occurs), the method 400 further includes comparing the noise value of the noise generation generation to the second noise threshold . As a result of the comparison, if the noise value of the noise generation generation exceeds the second noise threshold value, the noise generation signal may be transmitted to the noise generation generation device (or the noise generation generation device monitoring device 110). Here, the second noise threshold value may be a value larger than the noise threshold value for determining the noise generation generation.

In one embodiment, the method 400 includes transmitting a noise value and a vibration value of at least one of the generations and any associated generations to the any generation in response to the information request signal received from any generation Step < / RTI > After receiving the noise value and the vibration value, the gateway 230 included in the monitoring device 110 of any generation generates a home network or an information communication device (e.g., a wall pad, A mobile phone, a smart TV set-top box, etc.). According to an embodiment, the noise value and the vibration value transmitted to at least one of the information communication equipments include a current value of the noise value and the vibration value, an average value within a predetermined period, a peak value, a noise value and a vibration value exceeding a certain value Number of times, or time.

According to one embodiment, the noise values and vibration values transmitted to any generation may be defined by the noise values and vibration values of the generations associated with any generation and with any of the generations, wherein the generations associated with any generation are random And can be influenced by noise and can be determined from the information on the positional relationship between the generations.

A method of operating a noise management system in accordance with the present invention includes a computer readable medium having computer instructions for performing a method (400) of operating a noise management system (100) in accordance with an embodiment of the present invention, Lt; / RTI >

5 illustrates a premises 500 that includes a plurality of generations 510 through 590. In the example of FIG. 6 illustrates some generations 550 and 580 of the apartment house 500 shown in FIG.

1 to 6, there are a total of nine generations 510 to 590 in the apartment house 500, and generations (e.g., generations 510, generations 520, Generations 530 and 570) are positioned horizontally relative to each other to form one layer and the generations shown in the row direction (e.g., generation 510, generation 540, and generation 570) Noise can be generated.

In the housing 500, a noise management system 100 is installed. That is, the monitoring apparatus 110 is installed in each of the generations 510 to 590. The number of monitoring devices 110 may be the same as the number of generations 510 to 590 in the apartment house 500. A noise management device 120 may be installed outside the housing 550 to communicate with the monitoring device 110. The monitoring device 110 monitors the noise and vibration in the generations 510 to 590 in real time and transmits the monitored noise to the noise management device 120.

6, a generation unit 550 is provided with a noise measurement sensor 212, a vibration measurement sensor 222, and a gateway 232. The gateway 232 together with the noise measurement sensor 212, the vibration measurement sensor 222 and the information communication device 610 constitute a home network or a smart grid communication network. Similarly, generation 580 is equipped with a monitoring device 114 including a noise measurement sensor 214, a vibration measurement sensor 224 and a gateway 234. The gateway 234 together with the noise measurement sensor 214, the vibration measurement sensor 224 and the information communication device 620 constitute a home network or a smart grid communication network. The monitoring devices 112 and 114 may communicate with the noise management device 120 installed outside the generations 550 and 580.

Referring to FIGS. 5 and 6, a case in which inter-level noise occurs in the generation 550 by the generation 580 is illustrated. The noise measurement sensor 212 and the vibration measurement sensor 222 generate noise and vibration values by measuring noise and vibration generated in the generation 550, and then transmit the generated noise and vibration values to the gateway 232. The gateway 232 transmits the received noise value and the vibration value to the noise management device 120.

The noise management apparatus 120 may determine the generation 550 as a generation of noise when the noise value measured in the generation 550 exceeds a predetermined noise threshold value. Subsequently, the noise management apparatus 120 compares the vibration value measured in the generation 550 with a predetermined vibration threshold value, and when the vibration value measured in the generation 550 exceeds a predetermined vibration threshold value, Can be judged to have occurred. The noise management device 120 may determine the generation 580 that is in a position capable of generating interlayer noise for the generation 550 as the noise inducing generation and the generation 580 (or generation 580) monitoring device 114 )). ≪ / RTI > The monitoring device 114 of the household 580 may send a noise caution signal to at least one of the home network or an information communication device that constitutes the smart grid communication network (e.g., a wall pad, a cell phone, a smart TV set top box, etc.) have.

On the contrary, if the measured vibration value does not exceed the predetermined vibration threshold value, the noise management apparatus 120 may determine that the noise generated in the generation is not the interstage noise, and the noise management apparatus 120 includes the generation 550 ) May be determined as the own noise of the generation (550), and the generation (550) may be determined as the noise generation generation. Subsequently, the noise management apparatus 120 compares the noise value of the generation 550 with the second noise threshold, and then, when the noise value of the generation 550 exceeds the second noise threshold, the generation 550 Or the monitoring device 112 of the household 550). The monitoring device 112 of the household 550 can send a noise caution signal to at least one of the home network or an information communication device (e.g., a wall pad, a mobile phone, a smart TV set top box, etc.) have.

The embodiments presented herein may be implemented by hardware, software, firmware, middleware, microcode, or a combination thereof.

For a hardware implementation, the processing units may be implemented as one or more application specific integrated circuits (ASICs), digital signal processors (DSPs), digital signal processing devices (DSPDs), programmable logic devices (PLDs), field programmable gate arrays ), Processors, controllers, micro-controllers, microprocessors, other electronic units designed to perform the functions set forth herein, or a combination thereof.

When embodiments are implemented in software, firmware, middleware or microcode, program code or code segments, they may be stored in a machine-readable medium, such as a storage component. A code segment may represent any combination of procedures, functions, subprograms, programs, routines, subroutines, modules, software packages, classes or instructions, data structures, or program statements. A code segment may be coupled to another code segment or hardware circuit by transmitting and / or receiving information, data, arguments, parameters or memory contents. Information, arguments, parameters, data, etc. may be transmitted, forwarded or transmitted using any suitable means including memory sharing, message transmission, token transmission, network transmission,

For a software implementation, the techniques described herein may be implemented with modules (e.g., procedures, functions, and so on) that perform the functions described herein. The software codes may be stored in memory units and executed by processors. The memory unit may be implemented within the processor or external to the processor, and when implemented externally, the memory may be coupled to the processor via various means as is well known in the art.

As described above, an optimal embodiment has been disclosed in the drawings and specification. Although specific terms have been employed herein, they are used for purposes of illustration only and are not intended to limit the scope of the invention as defined in the claims or the claims. Therefore, those skilled in the art will appreciate that various modifications and equivalent embodiments are possible without departing from the scope of the present invention. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100 Noise management system 110 Monitoring device
120 Noise Management Device 210 Noise Measurement Sensor
220 Vibration measurement sensor 230 Gateway
310 interface module 320 database
330 control module

Claims (20)

A noise management system for a plurality of households constituting a multi-
At least one monitoring device installed in each household to measure noise and vibration in the household in real time; And
And a noise management device for determining a noise generation generation that generates noise from the noise value and the vibration value received from the monitoring device,
The noise management device includes:
An interface module for receiving the noise value and the vibration value from the monitoring device;
A database for storing the noise value and the vibration value, the information including a positional relationship between a plurality of generations constituting the apartment; And
A noise generation generation unit that compares the noise value with a predetermined noise threshold value to detect a noise generation generation having a noise value exceeding the noise threshold value and compares the vibration value measured at the noise generation generation with a predetermined vibration threshold value, And determining the noise-induced generation from the noise generation generation based on information on the positional relationship between the generations when it is determined that the interlayer noise is generated,
The monitoring device includes:
At least one noise measurement sensor for measuring the noise in the generation to generate the noise value;
At least one vibration measurement sensor for measuring vibrations within the generation to produce the vibration value, the vibration measurement sensor being located within the generation to measure vibrations transmitted from top to bottom; And
And a gateway for establishing a home network or a smart grid communication network including the noise measurement sensor and the vibration measurement sensor in each household and communicating with the noise management apparatus,
Wherein the control module determines the noise generation generation as the noise generation generation when it is determined that the interlayer noise does not occur. delete The method according to claim 1,
Wherein the noise value and the vibration value used by the control module for comparing with the noise threshold value and the vibration threshold value are determined by the current value of the noise value and the vibration value, the average value within a predetermined period, the peak value, And a value related to a time and a number of times each of the vibration values exceeds a certain value.
Noise management system. The method according to claim 1,
Wherein at least one of the noise threshold and the vibration threshold is variable over time or a different value is applied for each generation,
Noise management system. The method according to claim 1,
Wherein the vibration measurement sensor includes at least one of an acceleration sensor, an optical fiber sensor, and a piezoelectric vibration sensor,
Noise management system. The method according to claim 1,
Wherein the interface module transmits a noise alert signal to the monitoring device of the noise-
Wherein the gateway of the monitoring device of the noise generating household transmits the noise caution signal to at least one of a home network configured by the gateway or an information communication device included in a smart grid communication network after receiving the noise caution signal,
Noise management system. delete The method according to claim 1,
If the noise generation generation and the noise generation generation are the same generation, the control module compares the noise value measured in the noise generation generation with the second noise threshold,
Wherein the interface module transmits a noise warning signal to the monitoring device of the noise-induced generation when the noise value measured in the noise-induced generation exceeds the second noise threshold,
Wherein the gateway of the monitoring device of the noise generating household transmits the noise caution signal to at least one of a home network configured by the gateway or an information communication device included in a smart grid communication network after receiving the noise caution signal,
Noise management system. The method according to claim 1,
Responsive to an information request signal received from the monitoring device of any one of the generations, the interface module transmits a noise value and a vibration value of at least one of the generation and the associated generation to the monitoring ≪ / RTI >
Wherein the gateway of the monitoring device of any generation receives the noise value and the vibration value and transmits the noise value and the vibration value to at least one of the home network configured by the gateway or the information communication device included in the smart grid communication network, To transfer the value,
Noise management system. 10. The method of claim 9,
Wherein the noise value and the vibration value transmitted to at least one of the information communication equipments include at least one of a noise value and a current value of the vibration value, an average value within a predetermined period, a peak value, And a value related to a time.
Noise management system. CLAIMS 1. A method for operating a noise management system for a plurality of households constituting a multi-
Generating noise values by measuring noise in the generation in real time;
Generating vibration values by measuring vibrations in the generation in real time;
Comparing the noise value with a predetermined noise threshold value to detect a noise generation generation having a noise value exceeding the noise threshold value;
Comparing a vibration value measured in the noise generation generation with a predetermined vibration threshold value to determine whether or not an interlayer noise is generated; And
Determining the noise-induced generation from the noise generation generation based on the information on the positional relationship among the generations when it is determined that the interlayer noise is generated,
Further comprising determining the noise generation generation as the noise generation generation if it is determined that the interlayer noise does not occur. 12. The method of claim 11,
Further comprising storing the noise value and the vibration value.
How it works. 12. The method of claim 11,
Wherein the noise value and the vibration value used for comparing with the noise threshold value and the vibration threshold value are calculated based on a current value of each of the noise value and the vibration value, an average value within a predetermined period, a peak value, And a value related to the number of times each of the values exceeds a certain value.
How it works. 12. The method of claim 11,
Wherein at least one of the noise threshold and the vibration threshold is variable over time or a different value is applied for each generation,
How it works. 12. The method of claim 11,
Further comprising transmitting a noise caution signal to the noise-
How it works. delete 12. The method of claim 11,
Comparing the noise value measured in the noise-induced generation with a second noise threshold value when the noise generation generation and the noise generation generation are the same generation; And
Further comprising transmitting a noise caution signal to the noise-induced generation when the noise value measured at the noise-generating generation exceeds the second noise threshold.
How it works. 12. The method of claim 11,
Responsive to an information request signal received from any generation, transmitting noise values and vibration values of at least one of the generations and the generations associated therewith to the any generation,
How it works. 19. The method of claim 18,
Wherein the noise value and the vibration value transmitted to any one of the plurality of generations include a current value of the noise value and the vibration value, an average value and a peak value within a predetermined period, and the noise value and the vibration value, And a value relating to the number of times of exceedance and time.
How it works. A computer-readable medium comprising computer instructions for carrying out the method according to any one of claims 11 to 15 and 17 to 19.

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