RU2600663C1 - Method for compensation boiler control in accordance with ambient temperature using an external network - Google Patents

Abstract

FIELD: heat exchange.

SUBSTANCE: invention relates to a method for compensation heating temperature control in accordance with ambient air temperature, in which data on temperature come from an integration server without the need to install a separate ambient air temperature sensor. Control method using an external network comprises the following steps, recording a room controller on the integration server by transmitting a unique number of the controller, in which a wireless communication module is installed, by means of a wireless router; unique number identification on the integration server and preservation of unique number in the database; user addressing to the integration server by a terminal for inputting location information, corresponding unique number of the room controller, into the database; searching information on ambient air temperature in the area of installation of the room controller by means of the integration server, and transmitting data on ambient air temperature to the room controller; transmitting data on ambient air temperature, obtained from the room controller, to the boiler controller with compensation boiler control in accordance with ambient air temperature.

EFFECT: in compliance with this invention, there is no need for installation of a separate ambient air temperature sensor, because each boiler receives data on ambient air temperature of the relevant zone from the integration server by means of information on an IP-address or address information input by a user, invention allows preventing formation of icicles on a discharge pipe at ambient temperature below zero.

5 cl, 4 dwg

Description

FIELD OF THE INVENTION

The present invention relates to a method for controlling a boiler plant in accordance with an outdoor temperature, information about which comes from an external network, and in particular, to a method for compensating control of a boiler in accordance with an outdoor temperature using an external network that receives information about outdoor temperature from the integration server. In this case, there is no need to install a separate outdoor temperature sensor by providing a system configured to communicate between the room controller on which the wireless communication module is installed and the integration server, so as to compensate for the set temperature in accordance with the outdoor temperature to control the amount of heat supplied and to prevent the formation of icicles on the exhaust pipe, even if t outdoor air mperatura below zero.

State of the art

Ondol heating systems can, in general, be divided into local heating systems, district heating systems and district heating systems. To obtain perfect control in the Ondol heating system, the increase in heat and heat loss in the building should be equal. The processes of heat gain and heat reduction are dynamic processes that constantly change depending on the temperature of the outdoor air, solar radiation, infiltration, internal heat generation, etc., which leads to the need to control the amount of heat supplied inside the room.

For local heating systems, the temperature of the heating water is set by setting various seasonal criteria and for the winter season is 60-80 degrees. Despite the fact that the temperature of the heating water is set taking into account the seasonal outdoor temperature, the range of outdoor temperature fluctuations in the same season is not taken into account. In addition, daytime and nighttime, the south or server area, the parameters of the building (reaction to the temperature of the outside air), etc., are not taken into account, which causes problems such as excessive heating and energy loss.

To solve these problems, a technical solution is proposed, described in patent document No. 10-1109648, which discloses a pulsating flow control device having a feed line through which hot water is supplied; a hot water pipeline that diverts water from the supply line to each room so that the latent heat of the hot water is exchanged with each room; a return water supply connected to each hot water pipeline through which the water involved in the heat exchange is returned; an outdoor temperature sensor configured to measure an outdoor temperature; a controller issuing a control signal in accordance with the outdoor temperature obtained from the outdoor temperature sensor; a flow control valve mounted on the supply water pipe or on the return water pipe, receiving a control signal from the controller to control the flow of hot water flowing inside the pipe.

At the same time, in a conventional boiler system, the air entering from the outside through the supply ventilation pipe enters the burner with the fuel through the blower, and the exhaust gas resulting from combustion in the burner enters the heat exchange with the heating water transferred from the heat exchanger through circulation pump, and then released from the boiler into the atmosphere through the exhaust pipe.

The specified exhaust gas contains a significant amount of moisture (H ₂ O), however, since the temperature of the exhaust gas is usually more than 100 degrees, the moisture contained in the exhaust gas does not condense, but exits through the exhaust pipe in the form of steam.

However, if the outdoor temperature is very low, as is the case in winter, the temperature of the end of the exhaust pipe is much lower and thus the temperature of the exhaust gas can drop below the condensation temperature (usually up to 40-55 degrees, the temperature at which water vapor condensation begins contained in the exhaust gas). In this case, water vapor condenses at the end of the exhaust pipe.

In this case, in winter, when the outside temperature is below zero, the steam condensed in the end part of the exhaust pipe freezes, forming icicles. In addition to the fact that the presence of such icicles is undesirable from an aesthetic point of view, they pose a danger to people and materials if they fall from the top floor of a tall building.

To solve this problem, the solution described in Korean Patent No. 10-0805551, disclosing a method of preventing condensation in the exhaust pipe of the boiler, including the stages of the boiler, which carry out combustion; determining whether the outdoor temperature measured by the outdoor temperature sensor is lower than a predetermined temperature or not; switch the three-way valve to the hot water position if the measured outdoor temperature is lower than the set temperature; extinguish the burner if the temperature in the heating water pipe reaches a predetermined temperature; control the circulation pump and the blower so as to effect heat exchange in the main heat exchanger, and release hot air through the exhaust pipe.

The aforementioned known solutions have the disadvantage that both of them require a separate outdoor temperature sensor, mounted on the outer wall of the boiler air supply pipe, and connected to the boiler controller.

Known sources of information

Patent documents

Patent Document 1: Korean Patent No. 10-1109648

Patent Document 2: Korean Patent No. 10-0805551

Disclosure of invention

Object of the invention

The present invention is directed to solving these problems. The objective of the invention is to propose a method of compensatory control of the boiler in accordance with the outdoor temperature using an external network that forms a system in real time providing data on the outdoor temperature of the relevant zone by storing information about the user address and temperature information external air on the integration server, without a separate outdoor temperature sensor.

SUMMARY OF THE INVENTION

To solve this problem, the present invention proposed a method of compensatory control of the boiler in accordance with the outside temperature using an external network, characterized in that it includes the following steps: (a) registering the room controller by transmitting the unique number of the room controller in which it is installed wireless module, on the integration server via a wireless router, identifying a unique number on the integration server and then storing the unique a number in the database; (b) contacting the user or the tuner with the integration server via the terminal to enter location information corresponding to the unique number of the room controller into the specified database; (c) searching through an integration server for information about the outdoor temperature in the installation area of the room controller and transmitting information about the outdoor temperature to the room controller; and (d) transmitting information about the outdoor temperature obtained from the room controller to the boiler controller with compensating control of the boiler in accordance with the outdoor temperature.

Preferably, the method further includes the step of identifying the location information of the room controller on the integration server using the IP address of the wireless router and storing the location information of the room controller in the database.

In accordance with one embodiment, the compensatory control of the boiler in accordance with the outdoor temperature in step d) may primarily include controlling the flow rate of the supplied hot water by adjusting the degree of opening of the flow control valve in accordance with the change in the outdoor temperature.

Secondly, the temperature of the supplied heated water can be controlled depending on changes in the temperature of the surrounding air using a variable constant-coefficient K, which is in accordance with the set outdoor temperature.

Thirdly, they can switch the three-way valve to the hot water position when the outdoor temperature drops below zero, so that the expansion tank can store thermal energy while preventing the exhaust pipe from freezing.

Advantages of the Invention

In accordance with the present invention, there is no need to install a separate outdoor temperature sensor, since each boiler receives information on the outdoor temperature of the relevant area from the integration server via IP address information or address information entered by the user.

In addition, it becomes possible to actively control in accordance with changes in the temperature of the outdoor air so as to prevent overheating or loss of energy and always provide perfect heating. Also, the invention prevents the formation of icicles on the exhaust pipe, even if the temperature is below zero, and, therefore, to avoid damage to people or materials by falling icicles.

Brief Description of the Drawings

In FIG. 1 is a diagram illustrating a complete system configuration according to an embodiment of the present invention.

In FIG. 2 schematically shows the structure of a circulating flow control device in accordance with an outdoor temperature in accordance with an embodiment of the invention.

In FIG. 3 schematically shows the structure of an exhaust channel for preventing condensation on an exhaust pipe in accordance with an embodiment of the invention.

In FIG. 4 is a graph illustrating the relationship between a predetermined temperature of the supplied heating water and the temperature of the outside air when the coefficient K value changes in accordance with an embodiment of the invention.

The implementation of the invention

For a full understanding of the essence of the present invention, below with reference to the attached drawings describes an exemplary embodiment of its implementation. The specified embodiment provides for the possibility of various modifications and does not limit the scope of the invention. The following embodiment is provided in order to provide those skilled in the art with a more detailed description of the invention. Therefore, for greater clarity, in the drawings, the elements can be presented in an enlarged form. Identical or corresponding to each other elements in each drawing are denoted by the same reference numbers. In addition, a description of known functions or constructions is omitted, which would make it difficult to understand the invention.

Next, with reference to the accompanying drawings, an exemplary embodiment of the invention is described.

The method of compensatory control of the boiler in accordance with the outdoor temperature using an external network according to the present invention is divided essentially into the following steps:

(a) registering the room controller (110) on the integration server (130);

(b) transmitting outdoor temperature information from the integration server to the indoor controller (110);

(c) performing compensatory control of the boiler (100) in accordance with the outside temperature using the outside temperature information received from the room controller (110).

In the registration step of the room controller (110) on the integration server, as shown in FIG. 1, a room controller installed in the house is equipped with a wireless communication module (111) to enable wireless communication, and a unique number is entered for each product.

Thus, when the room controller (110) is connected to the wireless router (120) installed in the house, the specified unique number is transmitted wirelessly, the wireless router receives the specified unique number and sends it again to the integration server (130).

The integration server (130) contains an identification server (131) and a database (135) for performing the identification step, where they analyze the received unique number and determine if it is correct, and after the identification is completed, the unique number is stored in the database (135).

Two steps can be used to carry out the step of transmitting information about the outdoor temperature from the integration server (130) to the room controller (110).

The first method involves the participation of a user or installer entering address information, and for access to the integration server, the user or installer uses a terminal (140), such as a smartphone, personal computer or laptop, to enter a unique number, and then enters the address information about the zone in which the room controller (110) is installed. Address information is stored in a database (135) along with a unique number. After that, if the function of compensation control is provided in the room controller (110) in accordance with the outdoor temperature, the address information and the unique number of the room controller (110) are searched in the service server (132), which searches and updates temperature data in real time the outdoor air of each zone throughout the country in order to transmit real-time information about the outdoor temperature of the relevant zone to the room controller (110) at the appointed time.

In accordance with the second method, the user does not enter the address information, while the integration server (130) retrieves the IP address (IP address, short for English Internet Protocol Address) of the wireless router (120), which made wireless communication with the room controller (110) , for an approximate identification of the access zone using the Korea Network Information Center (krnic: http: //), etc., and stores the relevant location information in a database (135). The subsequent process of transmitting information about the outdoor temperature to the room controller (100) is identical to the above.

The room controller (110), which received information on the outdoor temperature in the previous step, transmits information on the outdoor temperature to the controller (101) of the boiler (100) via wired communication, for example, using the RS485 standard, to perform compensation control in accordance with the temperature outside air.

On the other hand, although the room controller (110) is described above as a necessary element in the process of transmitting outdoor temperature information from the integration server (130) to the controller (101), the concept of “room controller” covers all devices, such as the panel part, connected to the boiler, which can transmit and receive information about the outside temperature in a manner similar to that described above.

The prior art various embodiments of the compensation control in accordance with the outdoor temperature. The following describes embodiments of a control method that can increase energy efficiency by controlling the amount of heat supplied in accordance with the outdoor temperature and a control method that can prevent icicles from forming on the exhaust pipe when the outdoor temperature is below zero.

First of all, it is possible to use both methods: the method of controlling the flow rate and the method of controlling the temperature of the heating water supply to control the amount of heat supplied in accordance with the outdoor temperature.

As shown in FIG. 2, the circulating flow control device according to the outdoor temperature includes a supply pipe (210), a hot water distribution header (220), a hot water pipe (230), a hot water return header (240), a return pipe (250), and flow control valve (260).

The hot water pipe (230) leaves the collector (220) of hot water so that its branches enter each room, and the latent heat of the hot water enters the heat exchange with each room. Hot water enters the heat exchange with the floor when it flows through the hot water pipe (230), thereby heating the floor. The hot water is then cooled and returned through the hot water return manifold (240).

The controller (101) receives information about the outdoor temperature from the room controller (110) and controls the flow control valve (260), giving a control signal in accordance with the outdoor temperature.

A flow control valve (260) is installed on the supply pipe (210) or return pipe (250) and controls the flow of hot water flowing in the supply pipe (210) or return pipe (250) after receiving a control signal from the controller (101).

That is, as the outdoor temperature rises, the controller (101) controls the flow control valve (260) so as to reduce the flow of hot water. However, since the flow rate of the supplied water is low, the flow rate of hot water is reduced, which leads to more than enough time for heat transfer and thus increase energy efficiency. On the other hand, according to the method for controlling the temperature of the supplied heating water in accordance with the temperature of the outdoor air, the heating is controlled by the controller (101), which receives information about the outdoor temperature from the room controller (110) and determines the temperature of the supplied heated water in accordance with a variable constant ( coefficient K), which corresponds to a predetermined outdoor temperature. Here, the maximum detectable temperature of the supplied heating water is limited to 80 degrees and the operation of the boiler stops if it drops below 30 degrees. Thus, unlike traditional methods of proportional control, the proposed method provides the opportunity to reduce energy consumption for unnecessary heating.

In FIG. 4 is a traditionally used graph illustrating the relationship between the set temperature of the supplied heating water and the temperature of the outdoor air in accordance with the coefficient K. Moreover, the initial value of the coefficient K is 1 and this coefficient is a value calculated by applying a compensation rate in accordance with the temperature of the outdoor air, but can be changed by the installer or user.

Next, with reference to FIG. Figure 3 describes a method for preventing the formation of icicles on the exhaust pipe of the boiler.

During the operation of the boiler, the combustion process occurs. When the outdoor temperature, which is received from the room controller (110), reaches zero, the temperature at which the end of the exhaust pipe (360) can freeze, the controller (101) switches the three-way valve (390) to the hot water position to direct the flow of heating water toward the heat exchanger (380) of hot water, blocking the flow of heating water toward the pipeline (310) of heating water, in which heat exchange with the floor occurs. In this case, combustion typically continues in the burner (330).

In this example, the heating water is circulated through a circulation pump (350) in a closed circuit including a circulation pump (350), a main heat exchanger (340), a three-way valve (390), a hot water heat exchanger (380) and an expansion tank (370 ) Preferably, the flow pattern is such that the heating water passes through an expansion tank (370).

Typically, the expansion tank (370) can store about 4-8 liters of heating water and if combustion occurs when the three-way valve (390) is switched to the hot water position, the heating water circulating in a closed circuit is heated, thereby the expansion tank (370) performs the function of storing thermal energy, which can prevent freezing of the end of the exhaust pipe (360).

The temperature of the heating water flowing inside the pipe is determined by a sensor for measuring the temperature of the heating water (not shown in the drawing) and the controller (101) determines whether the measured temperature of the heating water has reached a predetermined value. If the indicated temperature has reached this value, the controller regards it as the temperature at which the end part of the exhaust pipe (360) will not freeze, and starts the quenching process.

Preferably, the predetermined temperature of the heating water at which the burner is extinguished (330) is equal to the maximum temperature that the heating water circulating in a closed circuit including an expansion tank (370) can be reached with a three-way valve (390) switched to the hot water position. Typically, the temperature of the heating water inside the pipe can be raised to 80-85 degrees, however, the maximum temperature can be determined experimentally, if you specify a flow pattern through which the heating water circulates.

During combustion, a circulation pump (350) and a blower fan (320) are operated, and the air carried by the blower fan (320) is heated by heat exchange with heating water heated in the main heat exchanger (340) during the above process. This air prevents freezing of the end of the exhaust pipe (360) by contacting with steam or drops of condensed water on the end of the exhaust pipe (360) as it exits through the exhaust pipe (360).

The above-described embodiment of the method of compensatory control of the boiler in accordance with the outdoor temperature using an external network according to the present invention is given only as an illustrative example. One skilled in the art will appreciate that various modifications and other similar embodiments are possible that can be made based on the description. Thus, it is obvious that the invention is not limited to the described embodiment. Accordingly, the scope of protection provided by the invention is determined by the appended claims. Also, it is understood that various modifications, equivalents and replacements of elements are possible without deviating from the scope and essence of the invention disclosed in the attached claims.

List of item numbers

100 - boiler

101 - controller

110 - room controller

111 - wireless module

120 - wireless router

130 - integration server

131 - authentication server

132 - service server

135 - database

140 - terminal

151 - direct-flow water

152 - hot water

Claims (5)

1. The method of compensatory control of the boiler in accordance with the outside temperature using an external network, which includes the following steps:
(a) registering the room controller on the integration server by transmitting the unique number of the room controller in which the wireless module is installed using a wireless router, identifying the unique number on the integration server and then storing the unique number in the database;
(b) contacting the user or the tuner with the integration server via the terminal to enter location information corresponding to the unique number of the room controller into the specified database;
(c) searching through an integration server for information about the outdoor temperature in the installation area of the room controller and transmitting information about the outdoor temperature to the room controller; and
(d) transmitting information about the outdoor temperature received from the room controller to the boiler controller with compensating control of the boiler in accordance with the outdoor temperature. 2. The method of claim 1, further comprising the step of identifying the location information of the room controller on the integration server using the IP address of the wireless router and storing the location information of the room controller in the specified database. 3. The method according to p. 1 or 2, in which the compensatory control of the boiler is carried out by controlling the flow rate of the supplied hot water by adjusting the degree of opening of the flow control valve in accordance with a change in the temperature of the outdoor air. 4. The method according to p. 1 or 2, in which the compensatory control of the boiler is carried out by controlling the temperature of the supplied heating water in accordance with the change in the temperature of the outdoor air using a variable constant value - coefficient K, which corresponds to a given temperature of the outdoor air. 5. The method according to claim 1 or 2, in which the compensatory control of the boiler involves switching the three-way valve to the hot water position when the outside temperature drops below zero, so that the expansion tank can store thermal energy, preventing the exhaust pipe from freezing.

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