KR20150079311A - electric power production of cogeneration system for home-use - Google Patents

Abstract

The present invention relates to a method to produce power of a cogeneration system for home use, capable of using even heat, generated from the production of electricity, as heating energy, increasing energy efficiency without power transmission loss since production and consumption are performed at the same place, and minimizing the consumption of energy by generating power by using electricity supplied from an electricity supplier in a section using a small amount of monthly graduated power rates but using cogeneration in a section using a large amount of graduated power rates. The method includes a first step (S21) of confirming an electricity price per supply gas and calculating PMOC which is a calculation value of the periodical optimal usage of external power; a step (S22) of determining whether it is the initial power generation of a period or not; a step (S23) of calculating PCOT, which is the total usage from a period for calculating power rates to the present, if it is not the initial power generation at the step (S22); a fourth step (S24) of calculating PDBC which is a calculation value of a daily generation amount; a step (S25) of operating cogeneration, and accumulating the daily generation amount; and a step (S26) of determining whether daily power generation is completed or not.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a power generation method for a home cogeneration system,

The present invention relates to a power generation method for a domestic cogeneration system, and more particularly, to a power generation method for a domestic cogeneration system, and more particularly, In the period where the monthly electricity consumed by the household is used less, the electric power supplied by the electricity supplier is used in the section where the electric power progressive fee is used less and the electric power is generated by using the cogeneration power in the section where the progressive fee is applied The present invention relates to a power generation method for a domestic cogeneration system that minimizes energy consumption.

According to No. 10-2006-0084542 (an energy-saving hybrid heating system in which a city gas fuels source is connected to individual heating and central heating of cogeneration power generation), "a region using a city gas such as LPG or LNG as a fuel source and a cogeneration power as a heat source In the heating system, the heating water is produced by using the waste heat such as the additional heat generated from the electricity generation and the arrangement, and the heating heat is supplied to each household or the building office of the apartment complex through the pipe network, and a plurality of hot water heat exchangers and heating heat exchangers are installed It is easy to use because it is possible to control the amount of usage because it can control the amount of usage by the pipe network structure which is connected with the existing individual boiler heating system to share heat energy. It is convenient and economical and easy to use. To provide the benefits of individual heating. It is possible to selectively implement intermittent heating and hot water supply operation as well as continuous heating, thereby saving facility costs due to miniaturization of boiler and improving efficiency of heat due to economical operation. It is an energy-saving hybrid heating system that links heating. "

Patent Document 10-2006-0084542 (Energy Saving Type Combined Heating System in which Municipal Gas Fuel Source Individual Heating and Central Heating for Cogeneration are Connected)

As life has been improved, energy consumption in the home has been increasing. Accordingly, various methods are being used to effectively reduce the cost of energy. The household cogeneration system can generate electricity and use the generated heat as heating energy. Since the distance between the consuming household and the supplying power station is not so long as the electric power supplied by the electric company is, Is high. Since the household cogeneration system using fuel cell or gas engine operates dynamically whenever necessary, there is a durability problem when it is frequently turned on / off. Therefore, ) Cycle. The domestic electricity bill calculation method is a multilevel electricity quantity progress system. If the electricity consumed by the electric utility only consumes electricity, the cost is increased. However, when the electric utility bill is used in a small amount, the cost generated by the household cogeneration system Cost.

Due to these problems, it is necessary to produce adequate generation amount in the domestic cogeneration system. However, the amount of electricity generated until now can not be known whether the electricity generated by the household cogeneration system can be appropriately developed in response to the electricity consumption cost by using the method of setting the electricity generation by the senses simply by consumers, .

In the case of Korea, the electricity tariff system of electricity providers is multi-level (6 levels), so the ratio between the lowest level and the highest level is 10 times or more different. Therefore, it is impossible to reduce the power consumption cost by using the cogeneration system in the case of the powerless household, and even in the case of the power-consuming household, Avoiding consumption is a way to reduce power usage costs. By comparing the production cost per kWh used to generate electricity in the household cogeneration system and the progressive electricity rate provided by the electric utility, it is confirmed that the progressive electric charge phase is used less than the cost of the household cogeneration system, So that it is possible to generate cogeneration power at a predetermined time. In addition, the electricity and gas charges are periodically changed, so the comparison fee for them should also be changed. The charge step calculation is implemented so that the administrator can communicate with the server through the WIFI without directly inputting the change contents.

Accordingly, an object of the present invention is to provide a method of heating energy generated by electricity generation, which can be used as heating energy, and has the same production and consumption places, In the section where the electric power progressive fee is low, the electric power supplied by the electric supplier is used. In the section where the progressive fee is applied, the electric power generated by the cogeneration power generation is minimized to the energy consumption of the household cogeneration system The purpose of the present invention is to provide a power generation method.

In order to achieve the above object, a heat generator unit including a cogeneration unit, a boiler and a hot water storage device, a system controller (13) for controlling cogeneration and heat source devices, a room controller Controller 14) will be described below.

The present invention is characterized by a first step (S21) of checking the electricity price per supply gas and calculating an optimal external electric energy usage calculation value P _MOC for each period; A second step (S22) of judging whether or not it is an early development of the period; A third step (S23) of calculating P _COT , which is the total amount of external power used up to the present from the period for calculating the electricity rate, if it is not the initial power generation in the second step (S22); A fourth step (S24) of calculating P _DBC which is a daily generation amount calculation value; A fifth step (S25) of starting the cogeneration and accumulating daily power generation; And a sixth step (S26) of judging whether the daily power generation is completed or not.

In the embodiment, if it is the initial power generation in the second step S22, it further includes a seventh step S27 of calculating P _BDA which is an average power generation amount of the previous period and branching to the fifth step S25.

In the embodiment, the daily power generation calculation value P _DBC is P _DBC = (P _UT / use period) - ((P _{MOC -} P _COT ) / remaining period)).

In the embodiment, the room controller receives the external power supply amount and the power generation amount value through the system controller, calculates the P _DBC through the received values, and transmits it to the system controller. Then, the system controller calculates the power generation amount of the cogeneration part To the controller to control the optimum power generation amount.

In the embodiment, in order to calculate and control the optimal amount of power generation, the system controller receives the unit price of the gas supply unit and the unit price from the user or the manager through the room controller.

According to the preferred effect of the present invention, when the progressive step for the current electricity rate is entered, a comparison is made between the power generation cost and the progressive electric power cost generated at home based on the amount of electric power used at home, Therefore, there is an advantage that it is possible to prevent a sudden increase in the electricity rate, and to prevent the blackout due to the sudden increase in the amount of electricity used nationwide. In addition, there is an advantage of establishing a base on which power can be temporarily used even when power supply is interrupted due to a disaster such as a typhoon or a war.

1 is a block diagram illustrating a system configuration for explaining a power generation method according to the present invention;
2 is a flowchart showing a power generation method according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a block diagram showing a system construction for explaining a power generation method according to the present invention. The domestic cogeneration system includes a cogeneration section 11, a heat source section 12 having a boiler and a hot water storage device, A system controller 13 for controlling the heat source device, and a room controller 14.

The cogeneration power generation unit 11 can measure the power supplied from the outside and calculate and calculate the generated power in addition to the function of generating power and generating hot water.

The heat source unit 12 includes a hot water tank for storing hot water generated from the cogeneration system and a boiler for increasing the hot water temperature when the hot water temperature of the hot water tank is low.

The household cogeneration system is provided with a cogeneration section, a heat source section having a boiler and a hot water storage device, a system controller 13 for controlling cogeneration and heat source devices, and a room controller 14 . The cogeneration section can measure the power supplied from the outside, as well as generating and generating hot water, and can check and calculate the amount of generated power. In the heat source unit, there is a hot water tank for storing hot water generated from the cogeneration power generation, and a boiler for increasing the hot water temperature when the hot water temperature of the hot water tank is low.

If the cogeneration is not done, the boiler will bear the burden of hot water generation. The main function of the system controller 13 is to check and calculate the amount of power and the hot water temperature to be generated in the cogeneration section and the heat source section according to the set value of the room controller 14, Thereby controlling the connection portion of the portion. The room controller 14 is a part in which the user sets functions for heating and power generation.

If the cogeneration is not done, the boiler will bear the burden of hot water generation. The main function of the system controller 13 is to check and calculate the amount of power and the hot water temperature to be generated in the cogeneration section and the heat source section according to the set value of the room controller 14, Thereby controlling the connection portion of the portion. The room controller 14 is a part in which the user sets functions for heating and power generation.

 The fuel used in the cogeneration section mainly uses gas, which results in a total efficiency of about 85 to 97%. Among them, the power generation efficiency is about 15 ~ 45%.

Domestic electricity tariffs use multi-level progressives, which are charged differently per kWh, depending on the amount of electricity used. Here, if less electricity is used during the electricity billing period, there may be a case where the charge of the external electricity supplier is lower than the electricity cost generated by the cogeneration power generation. Also, if the consumer sets the power generation amount in the room controller 14, it can not be known whether the power generation capacity is appropriately set.

The fuel used in the cogeneration section mainly uses gas, which results in a total efficiency of about 85 to 97%. Among them, the power generation efficiency is about 15 ~ 45%.

Domestic electricity tariffs use multi-level progressives, which are charged differently per kWh, depending on the amount of electricity used. Here, if less electricity is used during the electricity billing period, there may be a case where the charge of the external electricity supplier is lower than the electricity cost generated by the cogeneration power generation. Also, if the consumer sets the power generation amount in the room controller 14, it can not be known whether the power generation capacity is appropriately set.

In order to solve such a problem, we devised a method of calculating the amount of power generated in the cogeneration system by obtaining the amount of electricity used in the household during the period when the electricity rate is estimated. In the case of household cogeneration systems, considering the capacity, it is impossible to replace the amount of electricity consumed at one time to limit the amount of power supplied from the outside. In addition, depending on the characteristics of cogeneration power generation, if the power generation operation is started / stopped for a short period of time, life and durability become problems. Therefore, it is advantageous to calculate the power generation amount by checking the external power usage amount at a certain time during the period in which the electricity rate is calculated, and accordingly to generate power during one cycle of operation / stoppage.

Fig. 2 schematically shows a method of calculating the generation amount every day in order to develop an optimal amount of power per month.

2, a cogeneration power generation unit 11, a heat source unit 12 having a boiler and a hot water storage device, a system controller for controlling cogeneration and heat source devices, 13) 13, and a room controller (Room Controller 14).

Referring to FIG. 2, a first step S21 of checking the electricity price per supply gas and calculating the optimal external electric energy usage calculation value P _MOC for each period, Step S22 is performed.

If it is not the initial power generation in the second step S22, a third step S23 of calculating P _COT , which is the total amount of the external power from the period for calculating the electricity rate to the present, is performed, and then the daily power generation calculation value P A fourth step S24 of calculating the _DBC is performed.

The cogeneration system is operated and the fifth step S25 for accumulating the daily power generation amount is performed and then a sixth step S26 for determining whether the daily power generation is completed is performed.

If it is the initial power generation in the second step (S22), the average power generation amount P _BDA of the previous period is calculated and the seventh step (S27) for branching to the fifth step (S25) is performed.

Here, the P _DBC is calculated as follows.

P _DBC = (P _UT / Period of use) - ((P _MOC - P _COT ) / remaining period))

P _UT : Total electricity usage up to present during electricity bill calculation

P _COT : Total amount of external power from the period of calculating the electricity rate to present

P _MOC : Period (Monthly) Calculated value of optimum external power usage

P _DBC : daily power generation calculation value

The above P _DBC (The daily power generation calculation value) is calculated in the room controller 14, and the room controller 14 receives the external power supply amount and the power generation amount value through the system controller 13 in the cogeneration section. The system controller 13 calculates the P _DBC through the received values and transmits the value to the system controller 13. The system controller 13 controls the optimum power generation amount by transmitting the power generation amount of the cogeneration section.

In order to calculate the optimum power generation amount, it is necessary to know the gas supply unit price and the electricity unit price (step-by-step unit price), and the user or the manager can input the unit price through the room controller 14 and use it. However, the gas supply unit price is slightly different from region to region, and it is not frequently changed, but the electric charge system is also changed, so it may be a burden to the user or the manager to input. .

Therefore, there is a need to manage the gas and electricity tariff system in one place. Such a problem can be solved by implementing the WIFI function in the room controller 14 for management in one place and providing the gas charge information and the electric charge information from the external server (tentative fee server) to the room controller 14 .

11; Cogeneration section 12; The heat source unit
13; A system controller 14; Room Controller

Claims (6)

A cogeneration unit 11, a heat source unit 12 having a boiler and a hot water storage device, a system controller 13 for controlling cogeneration and heat source devices, a room controller 13, A method of generating power for a domestic cogeneration system having a room controller (14) (14)
A first step (S21) of checking the electricity price per supply gas and calculating an optimal external electric energy usage calculation value P _MOC for each period;
A second step (S22) of judging whether or not it is an early development of the period;
A third step (S23) of calculating P _COT , which is the total amount of external power used up to the present from the period for calculating the electricity rate, if it is not the initial power generation in the second step (S22);
A fourth step (S24) of calculating P _DBC which is a daily generation amount calculation value;
A fifth step (S25) of starting the cogeneration and accumulating daily power generation;
And a sixth step (S26) of judging whether the daily power generation is completed or not.
The method according to claim 1,
And a seventh step (S27) of calculating P _BDA, which is an average daily power generation amount of the previous period, in the second step (S22), and branching to the fifth step (S25) Production method.
The method according to claim 1,
Wherein the daily power generation calculation value P _DBC is P _DBC = (P _UT / use period) - ((P _MOC -P _COT ) / remaining period)).
The method of claim 3,
The room controller 14 receives external power supply amount and power generation amount value through the system controller 13 and calculates P _DBC through the received values and transmits it to the system controller 13, Wherein the power generation amount of the cogeneration section is transmitted to the room controller (14) to control the optimum power generation amount.
The method of claim 4,
The system controller (13) receives the input of the gas supply unit price and the unit price from the user or the manager through the room controller (14) in order to calculate and control the optimum power generation amount. Way.
The method of claim 4,
In order to calculate and control the optimal amount of power generation, the system controller 13 is equipped with a fee server externally provided with electricity rate information and gas rate information connectable to the Internet, and is provided from the room controller 14 to the fee server And collecting the electricity price information and the gas price information to collect the unit price.

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