KR20170004182A - Gas usage detecting method of a boiler only using network and detecting server for the same - Google Patents

Abstract

The present invention relates to a method of detecting a boiler gas usage through a network, which is able to detect and provide the boiler gas usage only without installing an extra gas meter, and a detecting server for the same. The present invention comprises: a step of registering the boiler; a step of analyzing the boiler; a step of calculating burn time; a step of calculating the amount of gas usage; and a step of providing the usage.

Description

[0001] The present invention relates to a method and apparatus for detecting a single gas consumption in a boiler using a network,

The present invention relates to a method of detecting a single gas consumption amount of a boiler using a network capable of detecting and providing only a gas consumption amount used in a boiler through a network without installing a separate gas meter in a boiler and a detection server therefor .

In general, gas meters are installed in household, industrial and office spaces to provide gas usage. Recently, gas meters have been provided by smart gas meters using the Internet.

However, the conventional smart gas meter only provides the gas consumption amount of the entire furniture through the main valve or the like, and has a problem that the gas consumption amount used in the boiler can not be provided alone.

In Korean Patent No. 10-0223302, the gas valve of the boiler is monitored to provide information on the gas utilization rate of the boiler alone, and in Korean Patent No. 10-1043894, the number of revolutions of the drive fan is monitored, It tells the usage amount.

However, such a conventional boiler-only gas meter requires a separate gas meter to be installed in the boiler, so that it is not possible to provide gas meter information of the boiler alone unless the gas meter is installed.

Korean Registered Patent No. 10-0223302 " How to display gas usage charge of gas boiler " Korean Patent No. 10-1043894 'Boiler control device capable of displaying and setting gas consumption amount and method thereof'

The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a boiler-independent gas generator using a network capable of detecting and using only a gas consumption amount used in a boiler through a network, An amount of usage detection method and a detection server therefor.

To this end, a boiler-only gas consumption detection method using a network according to the present invention includes: a boiler registration step of receiving and registering model information of a boiler being used after installation; A boiler analysis step of searching operation performance of the boiler stored in the DB with reference to the registered model of the boiler; A combustion time accumulating step of accumulating and accumulating combustion time information which is obtained by igniting the fuel gas in use by the boiler in use; Calculating a usage amount of the fuel gas using the operation performance of the boiler and the accumulated combustion time; And a usage amount providing step of providing the calculated gas usage amount to the information providing requester.

At this time, in the boiler analysis step, the DB is searched to retrieve the maximum fuel consumption amount, the efficiency and the operation load ratio of the boiler for each boiler of each model, and in the gas consumption calculation step, It is preferable to calculate the gas consumption amount.

[Equation 1] Gas consumption = (boiler maximum fuel consumption amount / gas heating amount) × efficiency × operation load ratio × combustion time

In addition, in the boiler registration step, it is preferable that the model information of the boiler is input and registered through the Internet of Things (IoT).

Meanwhile, the boiler-only gas consumption detection server using the network according to the present invention includes a boiler model registration unit for receiving and registering model information of a boiler being used after installation through a communication interface; A boiler performance DB storing operation performance information for each boiler model; A search unit for searching the operation performance of the boiler by referring to the registered model of the boiler; A combustion time accumulating unit for accumulating and accumulating combustion time information of the used boiler by igniting the fuel gas; A fuel consumption calculating unit for calculating an amount of use of the fuel gas by using the operation performance of the boiler and the accumulated combustion time; And a central processing unit that controls the calculated gas usage amount to be provided to the information providing requester through the communication interface.

The present invention as described above enables a model of a boiler to be obtained through a network such as the Internet (IoT), and to calculate the gas consumption amount of the boiler by assigning the model to the integrated combustion time. Therefore, it is possible to detect and supply the gas usage amount used in the boiler independently without installing a separate gas meter in the boiler.

FIG. 1 is a flowchart illustrating a method of detecting a single gas consumption of a boiler using a network according to the present invention.
2 is a block diagram of a system for detecting a single gas consumption of a boiler using a network according to the present invention.
3 is a block diagram of a boiler-only gas consumption detection server using a network according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a method for detecting a single gas consumption of a boiler using a network according to a preferred embodiment of the present invention and a server therefor will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, the method for detecting a single gas consumption amount of a boiler using a network according to the present invention includes a boiler registration step S110, a boiler analysis step S120, a combustion time integration step S130, a gas consumption calculation step S140, And a usage amount providing step (S150).

In this case, the boiler registration step (S110) is a step of receiving and registering model information of a boiler (see 200 in FIG. 2). The boiler 200 is installed in various types of boilers (200).

The model information may be any information unique to the boiler 200, such as a unique IP address (or MAC address) assigned to the boiler 200, a product number, or a bar code.

The model information is registered by being transmitted to a detection server (refer to '100' in FIG. 2) and is registered in a smart phone (see 210 in FIG. 2) or a personal PC (see 220 in FIG. 2) Alternatively, the detection server 200 may directly access the boiler 200 through the Internet (IoT) and automatically check it.

Next, in the boiler analysis step S120, the operation performance of the corresponding boiler 200 stored in the DB (see 130 in FIG. 3) is retrieved by referring to the model of the boiler 200 registered as described above. The operating performance of the searched boiler 200 is used to indirectly calculate the fuel gas usage.

The present invention is characterized in that the gas meter used for directly calculating the fuel gas consumption amount is not additionally installed in the boiler 200 but is used for detecting the amount of gas used alone in the boiler 200, use.

To this end, the operation performance of the boiler 200 used in the present invention includes the maximum fuel consumption amount, the efficiency and the operation load ratio of the boiler 200, which are characteristics of each model of the boilers 200, It is used to calculate usage amount.

Next, in the combustion time integration step (S130), the boiler 200 in use carries out the combustion time information which is operated by igniting the fuel gas, and integrates the combustion time information. The combustion time is also provided from the user to the detection server 100, so that the detection server 100 calculates the usage per unit time for each boiler model and multiplies the integrated combustion time.

The combustion time is typically extracted from the operating time when the operation of the boiler 200 is stopped from the point in time when the burner of the boiler 200 is ignited when the gas valve is open and is preferably extracted from the boiler 200 ) And accumulates the combustion time.

Next, in the gas usage calculation step S140, the usage amount of the fuel gas used alone in the boiler 200 is calculated using the operation performance of the boiler 200 and the accumulated combustion time, which are searched or collected as described above.

At this time, in the gas usage calculation step S140, the gas consumption amount is calculated by the following formula (1). The maximum fuel consumption amount, efficiency and operation load ratio of the boiler 200 are the same for each model of the boiler 200 can be different.

[Equation 1]

Gas consumption = (boiler maximum fuel consumption ÷ gas heating value) × efficiency × operating load rate × combustion time

The maximum amount of fuel consumed by the boiler 200 is a unit of [Kcal / h], and the calorific value of the gas commonly applied to each boiler 200 is [Kcal / Nm ³ ] The usage amount [Nm ³ / h] is calculated.

Further, in the present invention, the efficiency [%] of the boiler 200 and the operation load ratio [%] are further multiplied by the usage amount calculated as described above to more accurately calculate the fuel gas usage amount per model of the boiler 200.

For example, the maximum fuel consumption of the registered boiler 200 is 19,900 Kcal / h, the calorific value of the city gas is 9,500 Kcal / Nm ³ , the boiler 200 efficiency is 84%, the boiler 200 operating load ratio is 80% , The fuel gas consumption per hour becomes 1.94 Nm ³ / h, so that the daily, weekly, and monthly usage amounts can be deduced by multiplying the combustion time accumulated here.

Next, in the use amount providing step (S150), the gas use amount calculated in the gas use amount calculating step (S140) is provided to the information providing requester as described above.

The information can be provided by a user of the boiler 200 directly contacting the detection server 100 of the present invention with a smartphone or the like or by using a display device provided in the boiler 200 And can be provided in a variety of ways.

Hereinafter, the boiler-only gas consumption detection server using the network according to the present invention for detecting the gas consumption amount in the above-described manner will be described.

As shown in FIG. 2, the detection server 100 according to the present invention is connected to the boiler 200 through a network such as the Internet, and is typically connected to the boiler 200 using the object Internet protocol.

The user may access the detection server 100 through the smart phone 210 or the personal computer 220. The user may use the model of the boiler 200 as the connection ID, Can be identified.

The detection server 100 of the present invention includes the communication interface 110, the boiler model registration unit 120, the boiler performance DB 130, the search unit 140, the combustion time integration unit 150, A fuel consumption calculating unit 160, and a central processing unit 170. [

At this time, the boiler model registration unit 120 corresponds to a kind of storage device that receives and registers the model information of the boiler 200 being used after installation through the communication interface 110, and receives model information from the user side in which the boiler 200 is installed Input and register.

As the model information, unique information capable of specifying the boiler 200 is used. For example, various information such as a unique IP (or a MAC address) assigned to the boiler 200, a product number or a barcode may be used.

In addition, the boiler model is registered by being transmitted from the user to the detection server 100. At this time, the boiler model is input directly from the user's smartphone 210 through the app or directly to the boiler 200 through the Internet (IoT) And can be acquired automatically.

The boiler performance DB 130 stores operation performance information for each boiler model. The operating performance is indicative of the inherent characteristics of the boiler 200 manufactured and is used to indirectly calculate the amount of gas used.

The operation performance includes the maximum fuel consumption amount, the efficiency, and the operation load ratio, which are characteristics of each model of the boilers 200. The above-described gas calorific value is commonly applied to all the boilers 200, for example, . Of course, the calorific value may also be applied to different boilers.

Next, the search unit 140 searches the operation performance of the boiler 200 stored in the boiler performance DB 130 by referring to the model of the boiler 200 registered in the boiler model registration unit 120. That is, the operation performance of the boiler 200 is retrieved at a ratio of 1: 1 according to the model of the boiler.

The boiler 200 stored in the boiler performance DB 130 stores information on the discontinued boiler 200 as well as the currently sold model so that any user can be provided with the service of the present invention.

Next, the combustion time integrating unit 150 receives and accumulates the combustion time information that the boiler 200 in use is operated by igniting the fuel gas.

The combustion time is typically determined by using the time at which the operation of the boiler 200 is stopped from the point of time when the burner of the boiler 200 is ignited, preferably monitoring the operation of the boiler 200 via the object internet, .

Next, the fuel consumption calculation unit 160 calculates the amount of fuel gas consumption using the operation performance of the boiler 200 and the accumulated combustion time, and the calculation is based on the maximum fuel consumption amount of the boiler, the calorific value of the gas, The operating load ratio and the accumulated combustion time are used.

Next, the central processing unit 170 processes the overall process of the detection server 100 of the present invention as described above, and in particular, provides the calculated gas usage amount to the information providing requester through the communication interface 110. [

To this end, the central processing unit 170 provides information to the smartphone 210 or the personal computer 220 of the user connected to the server or transmits the information through the Internet to the display device provided in the boiler 200 or the like uniformly Provide information.

The specific embodiments of the present invention have been described above. It is to be understood, however, that the scope and spirit of the present invention is not limited to these specific embodiments, and that various modifications and changes may be made without departing from the spirit of the present invention. If you have, you will understand.

Therefore, it should be understood that the above-described embodiments are provided so that those skilled in the art can fully understand the scope of the present invention. Therefore, it should be understood that the embodiments are to be considered in all respects as illustrative and not restrictive, The invention is only defined by the scope of the claims.

100: detection server
110: Communication interface
120: Boiler model registration part
130: Boiler performance DB (DataBase)
140:
150: Combustion time integrating unit
160: fuel consumption calculation unit
170: central processing unit
200: Boiler
210: Smartphone
220: Personal PC

Claims (4)

A step (S110) of registering a boiler (200) for receiving and registering model information of a used boiler (200) after installation;
A boiler analysis step (S120) for searching the operation performance of the boiler (200) stored in the DB (130) by referring to the model of the registered boiler (200);
A combustion time integration step (S130) of transmitting and accumulating combustion time information of the boiler (200) in use, which is operated by igniting the fuel gas;
Calculating a usage amount of the fuel gas using the operation performance of the boiler (200) and the accumulated combustion time (S140); And
And providing a calculated amount of the used gas to the information providing requester (S150). The method according to claim 1,
In the boiler analysis step S120,
The DB is searched to retrieve the maximum fuel consumption amount, the efficiency and the operation load ratio of the boiler 200 for each boiler 200 of each model,
In the gas consumption calculation step S140,
Wherein the gas consumption amount is calculated by the following formula (1).
[Equation 1]
Gas consumption = (maximum fuel consumption of boiler (200) / gas heating value) × efficiency × operating load ratio × combustion time The method according to claim 1,
In the boiler 200 registration step S110,
Wherein the model information of the boiler (200) is inputted through the Internet of Things (IoT) and registered. A boiler model registration unit 120 for receiving and registering model information of the boiler 200 being used after installation through the communication interface 110;
A boiler performance DB 130 storing operation performance information for each boiler model;
A search unit (140) for searching the operation performance of the boiler (200) by referring to the model of the registered boiler (200);
A combustion time integrating unit 150 for receiving and accumulating the combustion time information that the boiler 200 in use is operated by igniting the fuel gas;
A fuel consumption calculation unit 160 for calculating an amount of use of the fuel gas using the operation performance of the boiler 200 and the accumulated combustion time; And
And a central processing unit (170) for controlling the supply of the calculated gas usage amount to the information providing requester through the communication interface (110).

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