KR20110006975A - Apparatus for regenerating heater having a function of external data detecting and control method thereof - Google Patents

Abstract

PURPOSE: A regenerative heater with an external data collection function and a control method thereof are provided to reduce energy consumption by collecting various data and performing heating depending on the collected data. CONSTITUTION: A regenerative heater with an external data collection function comprises an outdoor temperature detection unit(10), a heat storage heater(20), a heat storing temperature detection unit(30), a server(50), multiple fan heater(70,80,90), and a data processing/collecting device(60). The heat storage heater keeps heat using midnight electricity. The heat storing temperature detection unit detects the temperature of the heat storage heater. The server calculates the storage amount of heat based on the detected temperature and heats indoor by supplying the stored heat to the fan heaters. The data processing/collecting device transmits data from the server to the fan heaters and monitors the current state of the fan heaters.

Description

Application for regenerating heater having a function of external data detecting and control method

The present invention relates to a regenerative heating apparatus, and more particularly, to a regenerative heating apparatus having a function of collecting various data such as an external temperature change and thus collecting external data for more efficiently performing heat storage and heating operation. It relates to a control method.

As is well known, the term heating device refers to a device used for heating.

These heating devices can be broadly classified into: 1) small stoves, fireplaces, etc., in which fuel is directly burned and heated, 2) radiators are placed indoors, and heated by steam or hot water made by an outdoor boiler. Steam heating, hot water heating, ③ Heating the air with high temperature by heat gas, steam, hot water, electrothermal, etc., ie hot air heating, air conditioning, There is a variety of methods such as radiant heating to heat the surface temperature of walls, floors, and ceilings by sending hot water, hot air, etc., and using solar heat.

Recently, the use of regenerative heating devices, that is, regenerators, has been increasing for energy saving.

In general, a heat accumulator is a system that stores cold heat in a heat storage tank by using late-night electric power and uses this heat during a daytime cooling time, and it is widely used for improving load ratio by suppressing peaks in summer and increasing base load. . In the case of partial heat storage, a part of the daytime load is stored at night to accumulate and reduce the capacity of the freezer.In addition, the cooling capacity is excellent due to its ability to cope with each load with heat storage even under extreme load fluctuations. More favorable for buildings with large cooling capacity

However, the conventional regenerative heating device as described above has a problem in that it is operated regardless of various conditions such as external temperature change and thus does not use energy efficiently.

Accordingly, the present invention is to overcome the above-mentioned problems, heat storage type heating apparatus having a function of collecting a variety of data, such as the temperature change of the outside and accordingly collect the external data to perform the heat storage and heating operation more efficiently and The purpose is to provide the control method.

In order to achieve the above object, a heat storage heating device having a function of collecting external data according to the present invention, the heat storage heating device, comprising: an outdoor temperature detector for detecting an outdoor temperature; Regenerative heater for storing heat as a heater using a late night electricity; A heat storage temperature detector detecting a temperature of the heat storage heater; A server configured to control an operation state of the heat storage heater by calculating an amount of heat storage according to the outdoor temperature detected by the outdoor temperature detection unit, and to control the heating of the room by supplying the heat stored to the plurality of warmers; A plurality of warmers for heating the room; And a data processing / collecting device for transmitting the data of the server to the heater, inquiring and monitoring the current condition of the heater, and collecting and transmitting the data of the heater to the server.

The warm air fan, the temperature sensor for detecting the indoor temperature; Transmitting the indoor temperature detected by the temperature sensor to the data processing / collecting device, receiving a control command of the server from the data processing / collecting device to drive a heater and a fan, by grouping a hot air heater having the same heating conditions Simplify operation setting.

The apparatus further includes an integrated power meter that accumulates the amount of power accumulated by the operation time and the capacity.

The server may set a driving type such as a weekday, a holiday, a day before a holiday, a day after a holiday, or a Saturday according to a driving type setting, and specify a driving pattern in a group to generate a daily driving type.

The server may manage the entire and individual driving schedules according to the driving plan setting, and set the individual heating patterns, which are exceptional in the overall driving type setting and the driving type for each day.

The server may store the driving history in a separate memory and query the stored driving history information.

The server maintains the room temperature in the range of ± 1 ℃ of the room temperature set by heating fan ON / OFF control in case of heating operation, and in case of automatic, the room temperature according to the set temperature of the designated operation plan. Can be.

In the regenerative control, the server sets and accumulates a heat storage target amount in the manual mode, and calculates and accumulates an appropriate heat storage target amount in the eco mode in accordance with the transition between the outside air and the heat storage amount.

According to another aspect of the present invention, in a heat storage heating control method, when heating operation is started, first, acquiring an indoor temperature, and determining whether an error state and a heating time are performed to perform control; Determining the mode and reading a preset operation plan and a set temperature from the memory to the server in the automatic mode, and performing a manual operation in the manual mode and reading the set temperature accordingly; Performing indoor heating according to the indoor temperature by setting the indoor temperature to a preset temperature by judging the indoor temperature by comparing with the preset temperature; And storing the operation history according to the room temperature in the memory.

Another aspect of the present invention provides a regenerative heating control method, comprising: collecting information of a hot air fan and performing error state and heat storage time control accordingly; Calculating a heat storage target temperature and a heat storage start time in the automatic mode by determining the mode, and performing a manual operation in the manual mode, and reading the set temperature accordingly; Performing heat storage control according to the heat storage temperature by controlling the heater on / off by comparing the heat storage temperature with the set temperature; And storing the operation history according to the heat storage temperature in a memory.

According to the regenerative heating device having a function of collecting external data according to the present invention and a control method thereof, it is possible to prevent unnecessary energy waste by collecting various data such as external temperature change and thus more efficiently performing heat storage and heating operation. It works.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The terms or words used in this specification and claims are not to be construed as limiting in their usual or dictionary meanings, and the inventors may properly define the concept of terms in order to best explain their invention in the best way possible. It should be interpreted as meaning and concept corresponding to the technical idea of the present invention. Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

1 is a block diagram showing an embodiment of a regenerative heating device having a function of collecting external data according to the present invention.

As shown, the present invention, the outdoor temperature detector 10, the heat storage heater 20, the heat storage temperature detection unit 30, the integrated power meter 40, the server 50, the data processing / collecting device 60, a hot air heater 70, 80, 90, a control board 71, a temperature sensor 72, a heater 73, and a fan 74.

The outdoor temperature detector 10 detects an outdoor temperature. Depending on the detected outdoor temperature, the room temperature manual mode and automatic mode can be operated. In manual mode, heating can be controlled automatically within the target set temperature range of ± 1 ℃, and the daily constant temperature can be set. In the automatic mode, the room temperature can be automatically controlled and heated according to the operation pattern according to the set temperature for each time zone.

The heat storage heater 20 stores the heat as a heater using a late night electricity. At this time, it is possible to select a late night time (heat storage time).

The heat storage temperature detector 30 detects the temperature of the heat storage heater 20. Depending on the detected temperature, the thermal storage manual mode and automatic mode can be operated. In manual mode, it is possible to accumulate heat by setting the heat storage rate in%. In automatic mode, the heat storage temperature can be adjusted automatically to prevent unnecessary heat storage.

The integrated power meter 40 accumulates the amount of power integration by operating time and capacity.

The server 50 controls the operation state of the heat storage heater 20 by calculating the heat storage amount according to the outdoor temperature detected by the outdoor temperature detection unit 10, and stores the heat stored in the warm air heaters 70, 80, and 90. To heat the room. To this end, the server 50 outputs a control command to the warm air fan (70, 80, 90).

In addition, the server 50 may be set to drive, such as weekdays, holidays, days before holidays, days after holidays, Saturday, etc., depending on the type of operation. In addition, a driving pattern may be assigned to a group to generate a daily driving type.

In addition, it is possible to manage the entire and individual driving schedule according to the operation plan setting, and can set the individual operation pattern of the exceptional warmer in the overall operation type setting and operation type by day.

In addition, the driving history may be stored in a separate memory (not shown) and the stored driving history information may be inquired.

In heating operation, the room temperature can be maintained within the range of ± 1 ℃ of the room temperature setting by the heating fan ON / OFF control in case of manual operation, and the room temperature can be maintained according to the setting temperature of the designated operation plan in the case of automatic operation. .

In the heat storage control, in the manual mode, the heat storage target amount can be set and stored, and in the eco mode, the proper heat storage target amount can be calculated and stored in accordance with the transition between the outside air and the heat storage amount.

The data processing / collection device 60 transmits the data of the server 50 to the warmers 70, 80, and 90. In addition, the current state of the heaters 70, 80, 90 can be monitored and monitored, and the data of the heaters 70, 80, 90 are collected and transmitted to the server 50.

The warmers 70, 80, and 90 heat the room. To this end, the warm air heater 70, 80, 90 includes a control board 71, a temperature sensor 72, a heater 73 and a fan 74.

The warmers 70, 80, and 90 may group the warmers having the same heating conditions to simplify the operation setting. For example, up to 320 individual hot air blowers 70, 80, and 90 may be designated, and up to 99 hot air blower groups may be set.

The temperature sensor 72 detects the room temperature. The heating target temperature can be set up to 30 ° C. In addition, the indoor temperature can be preset in units of 24 hours and managed in one pattern.

The control board 71 transmits the room temperature detected by the temperature sensor 72 to the data processing / collection apparatus 60. In addition, the control board 71 receives a control command of the server 50 from the data processing / collection apparatus 60 to drive the heater 73 and the fan 74.

2 is a flowchart illustrating a heating operation process as an embodiment of a regenerative heating control method having a function of collecting external data according to the present invention.

As shown, when the heating operation of the present invention is started, first obtain the room temperature (S110), and determine whether the error state and the heating time to perform the control (S120).

Thereafter, the mode is determined (S130), in the automatic mode, the preset operation plan and the set temperature are read from the memory (not shown) to the server 50 (S140). On the other hand, in the manual mode, the manual operation is performed and the set temperature is read accordingly (S150).

Thereafter, the indoor temperature is determined by comparing with the set temperature (S160) to control the on / off fan to perform the heating of the room according to the set temperature. That is, the fan is turned on when the indoor temperature is lower than the set temperature, and the fan is turned off when the indoor temperature exceeds the set temperature (S170 to S180).

In addition, the operation history according to the room temperature is stored in the memory (S190).

3 is a flowchart illustrating a heat storage control process according to the present invention.

As shown, the heat storage control of the present invention, first collects the information of the hot air fan and performs the error state and heat storage time control accordingly (S210 ~ S220).

Thereafter, the mode is determined (S230) in the case of the automatic mode, the heat storage target temperature and the heat storage start time are calculated (S240). On the other hand, in the manual mode, the manual operation is performed and the set temperature is read accordingly (S250).

Thereafter, the heat storage temperature is compared with the set temperature (S260) and the heater is turned on / off to control the heat storage temperature according to the set temperature. That is, when the heat storage temperature is lower than the set temperature, the heater is turned on, and when the heat storage temperature exceeds the set temperature, the heater is turned off (S270 to S280).

In addition, the operation history according to the heat storage temperature is stored in the memory (S290).

4 is a flowchart illustrating a heating schedule planning process of the present invention.

As shown, the heating schedule plan setting process of the present invention, first inputting the warm fan information (S310). For example, information such as a hot air fan number, a real name, an area, and a floor is input.

Subsequently, a group for each hot air fan is set (S320), and operation patterns such as time unit setting and temperature management are set (S330).

Thereafter, in setting the driving type, a weekday, a holiday, driving information, etc. are set (S340).

Thereafter, a driving type for each day is designated, and at this time, the screen may be configured in a calendar form (S350).

Finally, by adjusting the non-work days and setting an exceptional operation plan, the heating schedule plan setting process is terminated (S360 to S370).

5 is a view showing a state of use of the present invention.

As shown, the server 50, the data processing / collecting device 60, and the heat fans 70, 80, 90 of the present invention are shown.

The interface of the data processing / collection apparatus 60 and the warmers 70, 80, and 90 may use RS485. In addition, in order to standardize communication, it is preferable to make communication parameters common.

The data processing / collecting device 60 performs periodic polling communication with the control board 71 of the heaters 70, 80, and 90 by RS485 communication.

Fig. 6 is a block diagram showing a data processing / collection apparatus of the present invention.

As shown, the data processing / acquisition device 60 of the present invention includes a power supply unit 61, a protocol processor 62, a data processor 63, an event processor 64, an Ethernet processor 65, and a serial processor 66. ).

The control board 71 is composed of DC power and Remote I / O (Signal I / F, Communication I / F), and must be distinguished with each unique ID or address (Address: 1 to 31).

7 is a diagram illustrating a data flow when requesting an event of the present invention.

As shown, when the server 50 of the present invention requests the event to the data processing / collecting device 60, the data processing / collecting device 60 transmits this event request to the warm air heater (70, 80, 90). do.

When the warmer 70, 80, 90 transmits response data to the data processing / collection apparatus 60, the data processing / collection apparatus 60 transmits event response data to the server 50.

8 is a diagram illustrating a data flow when an alarm and an event occur according to the present invention.

As shown, when the server 50 of the present invention requests the event to the data processing / collecting device 60, the data processing / collecting device 60 transmits this event request to the warm air heater (70, 80, 90). do.

When the heaters 70, 80, and 90 transmit alarm generation data to the data processing / collection apparatus 60, the data processing / collection apparatus 60 transmits the alarm data to the server 50 accordingly. The server 50 recognizes an alarm state.

9 is a control flowchart illustrating a data collection process of the present invention.

As shown, the present invention first selects the type of DAT to be used. For example, any one of DAT-50A / 100A / 150/200/1000 may be selected. In addition, one of three driver types can be selected as follows (Serial Only, Ethernet: Serial + Ethernet, SECS: Serial + Ethernet + SECS) (S401).

Then, the serial / Ethernet is selected according to the communication type (S420).

Thereafter, detailed setting of the selected port is performed (S430). For example, you can set the port as serial: 9600bps, 8 data bits, 1 stop bit, parity none.

Thereafter, it is determined whether to use an embedded dedicated protocol, for example, MODBUS RTU / ASCII / TCP, GLOFA CNET / ENET, MELSEC-Q, and SIEMENS 3964 (R) (S440).

When the dedicated protocol is used, an operation process for transmitting, receiving, and converting data is created (S450).

On the other hand, when the dedicated protocol is not used, a protocol other than the dedicated protocol is directly created by the user (S460).

In this way, when the creation of the process is completed, the completed program is downloaded to the DAT (S470).

10 is a block diagram showing a connection state of the warmer and the remote control of the present invention.

As shown, the warm air heater 70 of the present invention can be controlled remotely using the remote control 100.

To this end, the warm air fan 70 includes a wireless communication unit 75, a microcomputer 76, and a power supply unit 77. In addition, the remote controller 100 includes a key input unit 110, a display unit 120, a microcomputer 130, a wireless communication unit 140, and a rechargeable battery unit 150.

In addition, a cradle 200 having a charging terminal terminal 210 for charging the power of the remote control 100 is provided.

The charging terminal 210 of the cradle 200 is connected to the wire through the connection line from the power supply 77 of the warmer 70 is supplied with power, when the remote control 100 is mounted on the cradle 200 The terminal unit 210 contacts the rechargeable battery unit 150 to charge the rechargeable battery unit 150.

The key input unit 110 of the remote controller 100 inputs the current time, the reservation time and the set temperature of the warm air fan 70.

The display unit 120 displays time, set temperature, indoor / outdoor temperature, and heat storage amount of the heat storage heater.

The microcomputer 130 transmits the current time, the reservation time, and the set temperature input from the key input unit 110 to the wireless communication unit 140.

The wireless communication unit 140 transmits the current time, the reservation time, and the set temperature transmitted from the microcomputer 130 to the wireless communication unit 75 of the warm air fan 70.

The wireless communication unit 140, 75 may apply a conventional infrared wireless communication method.

The wireless communication unit 75 of the warmer 70 transmits the received current time, reservation time, and set temperature to the microcomputer 76, and the microcomputer 76 according to the transmitted current time, reservation time, and set temperature. Set).

The power supply unit 77 supplies power to the hot air heater 70 and is connected to the charging terminal 210 of the cradle 200 by wire.

As described above, the present invention has been described by way of limited embodiments and drawings, but the present invention is not limited to the above-described embodiments, which can be variously modified and modified by those skilled in the art to which the present invention pertains. Modifications are possible. Accordingly, the spirit of the present invention should be understood only by the claims set forth below, and all equivalent or equivalent modifications thereof will belong to the scope of the present invention.

1 is a block diagram showing an embodiment of a regenerative heating device having a function of collecting external data according to the present invention.

2 is a flowchart illustrating a heating operation process as an embodiment of a regenerative heating control method having a function of collecting external data according to the present invention;

3 is a flow chart showing a heat storage control process of the present invention.

4 is a flow chart showing a heating schedule planning process of the present invention.

5 is a view showing a state of use of the present invention.

Fig. 6 is a block diagram showing a data processing / collection apparatus of the present invention.

7 is a diagram illustrating a data flow when requesting an event of the present invention.

8 is a diagram illustrating a data flow when an alarm and an event occur according to the present invention.

9 is a control flowchart illustrating a data collection process of the present invention.

10 is a block diagram showing a connection state of the warmer and the remote control of the present invention.

<Explanation of symbols for the main parts of the drawings>

10: outdoor temperature detector 20: heat storage heater

30: heat storage temperature detector 40: integrated power meter

50: server 60: data processing / collecting device

70, 80, 90: Warmer 71: Control board

72: temperature sensor 73: heater

74: fan 75: wireless communication unit

76: microcomputer 77: power supply

100: remote controller 110: key input unit

120: display unit 130: microcomputer

140: wireless communication unit 150: rechargeable battery unit

200: cradle 210: charging terminal unit

Claims (11)

In the regenerative heating device, An outdoor temperature detector configured to detect an outdoor temperature; Regenerative heater for storing heat as a heater using a late night electricity; A heat storage temperature detector detecting a temperature of the heat storage heater; A server configured to control an operation state of the heat storage heater by calculating an amount of heat storage according to the outdoor temperature detected by the outdoor temperature detection unit, and to control the heating of the room by supplying the heat stored to the plurality of warmers; A plurality of warmers for heating the room; And a data processing / collecting device for transmitting the data of the server to the heater, inquiring and monitoring the current condition of the heater, and collecting and transmitting the data of the heater to the server. Having regenerative heating device. The method of claim 1, The warmer, A temperature sensor for detecting indoor temperature; Transmitting the indoor temperature detected by the temperature sensor to the data processing / collecting device, receiving a control command of the server from the data processing / collecting device to drive a heater and a fan, by grouping a hot air heater having the same heating conditions Regenerative heating device having a function of collecting external data, characterized in that to simplify the operation setting. The method of claim 1, A regenerative heating device having a function of collecting external data, further comprising an integrated power meter that accumulates the amount of power accumulated by the operating time and capacity. The method of claim 1, The server is Set the operation type by selecting any one among weekday, holiday, day before holiday, after holiday, and Saturday according to the setting of operation type, and specify the driving pattern to the group to create the daily operation type. Regenerative heating device having a. The method of claim 1, The server is A regenerative heating device having an external data collection function, which manages the entire and individual operation schedules according to the operation plan setting, and sets the individual operation patterns of the exceptional heat fans in the setting of the overall operation type for each day and the operation type. The method of claim 1, The server is A heat storage type heating device having a function of collecting external data, wherein the driving history is stored in a separate memory and the stored driving history information is inquired. The method of claim 1, The server is In the case of heating operation, the room temperature is maintained within the range of ± 1 ℃ of the room temperature setting by the heating fan ON / OFF control in case of manual operation, and the room temperature is maintained according to the setting temperature of the designated operation plan in the case of automatic operation. Regenerative heating device having a function of collecting external data. The method of claim 1, The server is In the heat storage control, in the manual mode, the heat storage target amount is set and stored, and in the eco mode, the heat storage type having the function of collecting external data is characterized by calculating and accumulating the proper heat storage target amount by the trend of the outside air and the heat storage amount. Device. The method of claim 1, The warmer further includes a remote control for controlling the operating state from the remote, The remote control A key input unit for inputting a current time, a reservation time of the hot air fan, and a set temperature; A display unit for displaying the time inputted from the key input unit, the set temperature, the indoor / outdoor temperature, and the heat storage amount of the heat storage heater; A microcomputer for transmitting the current time, the reservation time, and the set temperature inputted from the key input unit to the wireless communication unit 140; And a wireless communication unit for transmitting the current time, the reservation time, and the set temperature transmitted from the microcomputer to the wireless communication unit of the warm air fan, The warmer A wireless communication unit for receiving a current time, a reservation time, and a set temperature; A microcomputer that sets an operating state of the hot air heater according to the received current time, reservation time, and set temperature; It includes a power supply unit for supplying operating power to the warmer, In order to charge the power of the remote control provided with a cradle having a charging terminal, The charging terminal terminal unit of the cradle is connected to the wire through the connection line from the power supply unit of the warmer to receive power, and when the remote control is mounted on the cradle, the charging terminal terminal contacts the rechargeable battery unit to charge the rechargeable battery unit. Regenerative heating device with the ability to collect external data. In the regenerative heating control method, When the heating operation is started, first obtaining an indoor temperature, and determining whether an error state and a heating time are performed to perform control; Determining the mode and reading a preset operation plan and a set temperature from the memory to the server in the automatic mode, and performing a manual operation in the manual mode and reading the set temperature accordingly; Performing indoor heating according to the indoor temperature by setting the indoor temperature to a preset temperature by judging the indoor temperature by comparing with the preset temperature; A regenerative heating control method having a function of collecting external data, the method comprising storing an operation history according to an indoor temperature in a memory. In the regenerative heating control method, Collecting information of the hot air fan and performing error state and heat storage time control accordingly; Calculating a heat storage target temperature and a heat storage start time in the automatic mode by determining the mode, and performing a manual operation in the manual mode, and reading the set temperature accordingly; Performing heat storage control according to the heat storage temperature by controlling the heater on / off by comparing the heat storage temperature with the set temperature; And storing the operation history according to the heat storage temperature in a memory.

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