KR102377861B1 - Smart remote control hot air fan - Google Patents

Abstract

The present invention relates to a smart remote control heater. More specifically, it is automatically remote controlled and the fuel refueling state is recognized, so that not only can the operating status of the smart remote control heater be confirmed, but workers' entry and exit are minimized and carbon monoxide poisoning is achieved. This is about a smart remote control heater to provide safety management to prevent fatal accidents caused by etc.

Description

Smart remote control hot air fan}

The present invention relates to a smart remote control heater. More specifically, it is automatically remote controlled and the fuel refueling state is recognized, so that not only can the operating status of the smart remote control heater be confirmed, but workers' entry and exit are minimized and carbon monoxide poisoning is achieved. This is about a smart remote control heater to provide safety management to prevent fatal accidents caused by etc.

During winter framing and wet construction, a hot air blower is used to maintain the curing temperature. The hot air blower must be operated for more than 12 hours for curing, but the operating duration is usually 6 to 10 hours, so curing temperature management and lubrication are necessary. Workers needed frequent entry and exit, and there was the inconvenience of having to transport fuel tanks to higher floors every time.

In addition, fatal accidents continue to occur due to carbon monoxide poisoning due to incomplete combustion of heaters, and a recent incident of death due to carbon monoxide poisoning occurred at an apartment construction site, raising the need for safety management.

For curing management at such construction sites, a ubiquitous-based concrete curing management system and method were proposed (Patent Registration No. 10-0608148 (2006.07.26.)), but it is still difficult to understand the current state of the business in relation to the management of hot air blowers in the winter. Since it is related to technology, the issue of hot air blower management at construction sites in the winter remains a difficult issue, with concerns over quality deterioration when the curing temperature drops due to neglect of hot air fuel management.

Republic of Korea Patent Registration No. 10-0608148 (2006.07.26.) “Ubiquitous-based concrete curing management system and method”

The present invention is intended to solve the above problems. Not only can it check the operating status of a smart remote control heater by automatically controlling the remote control and recognizing the fuel refueling status, but also minimizing the entry and exit of workers, thereby enabling deaths due to carbon monoxide poisoning. The purpose is to provide a smart remote control heater to provide safety management to prevent accidents.

In addition, the present invention provides a quality control aspect that prevents concrete quality deterioration due to temperature decrease through frequent monitoring and control of internal temperature, and provides a smart remote control heater to provide smart safety and field management methods.

However, the objects of the present invention are not limited to the objects mentioned above, and other objects not mentioned will be clearly understood by those skilled in the art from the description below.

In order to achieve the above object, a smart remote control heater according to an embodiment of the present invention includes a fuel tank 190; A refueling hose 160 formed to deliver fuel to the fuel tank 190 through the automatic refueling cap 140 according to the operation of the built-in fuel pump 130 of the controller 180; A flow meter 150 that acquires flow rate information of the fuel tank 190 in real time and provides it to the controller 180; And when the flow rate information of the fuel tank 190 is less than the preset critical flow rate (20 to 25%), the auxiliary fuel connected to the opposite end of the fuel hose 160 rather than the end connected to the built-in fuel pump 130 of the controller 180. A controller 180 that automatically performs a function of charging fuel so that the flow rate of the fuel tank 190 corresponding to less than the critical flow rate from the tank 200 becomes the optimal charging flow rate (80 to 85%); It may be characterized as including.

At this time, the present invention includes a hot air device (100a); It may further include that the controller 180 receives an external remote control request through the wireless communication antenna 120 and controls the operation of the hot air device 100a.

In addition, the present invention includes a sensor module (150a) including a temperature sensor (151a) and a volatile organic compound sensor (TVOC) (152a); It may be characterized by further comprising:

In addition, in the present invention, the controller 180 not only receives temperature information and organic compound concentration information of the smart remote control heater 100 from the sensor module 150a, but also receives information from each fuel tank 190 from the flow meter 150. It may be characterized by acquiring and storing flow rate information in real time.

The smart remote control heater according to an embodiment of the present invention is automatically remote controlled and the fuel refueling state is recognized, so that not only can the operating status of the smart remote control heater be checked, but it also minimizes the entry and exit of workers to prevent carbon monoxide poisoning, etc. It is effective in providing safety management to prevent fatal accidents.

In addition, the smart remote control heater according to another embodiment of the present invention provides a quality control aspect that prevents concrete quality deterioration due to temperature decrease through frequent monitoring and control of internal temperature, and can provide smart safety and on-site management methods. Provides effective effects.

1 and 2 are diagrams showing a smart remote control heater 100 according to a first embodiment of the present invention.
3 and 4 are diagrams showing a smart remote control heater 100 according to a second embodiment of the present invention.

Hereinafter, a detailed description of preferred embodiments of the present invention will be described with reference to the attached drawings. In the following description of the present invention, if a detailed description of a related known function or configuration is judged to unnecessarily obscure the gist of the present invention, the detailed description will be omitted.

In this specification, when one component 'transmits' data or a signal to another component, the component may transmit the data or signal directly to the other component, and may transmit the data or signal through at least one other component. This means that data or signals can be transmitted to other components.

1 and 2 are diagrams showing a smart remote control heater 100 according to a first embodiment of the present invention. Referring to Figures 1 and 2, the smart remote control heater 100 includes a heater 100a, an indicator lamp 110, a wireless communication antenna 120, a built-in fuel pump 130, and an automatic refueling cap 140. , may include a flow meter 150, a sensor module 150a, a refueling hose 160, a power line 170, a controller 180, and a fuel tank 190, and the refueling hose 160 is connected to the controller 180. It is connected in such a way that fuel is delivered to the automatic refueling cap 140 according to the operation of the built-in fuel pump 130, and the power line 170 is connected to the controller 180 and the automatic refueling cap 140, respectively. You can have it. In addition, along with the smart remote control heater 100, an auxiliary fuel tank 200 is installed at the opposite end of the fuel hose 160 of the smart remote control heater 100, rather than the end connected to the built-in fuel pump 130 of the controller 180. ) has a structure in which it is placed.

Meanwhile, the sensor module 150a may include a temperature sensor 151a, a volatile organic compound (TVOC) sensor 152a, and a front camera 153a.

The controller 180 receives an external remote control request through the wireless communication antenna 120, controls the operation ON of the hot air device 100a, and then operates the sensor module 150a provided in the controller 180. In addition to receiving the temperature information and organic compound concentration information of the smart remote control heater 100, the flow rate information of each fuel tank 190 can be obtained in real time from the flow meter 150 and stored in its own memory.

The controller 180 is a first condition in which the flow rate information for each fuel tank 190 is less than a preset critical flow rate (20 to 25%), a second condition in which the flow rate information for each fuel tank 190 exceeds a preset critical flow rate of the heater, or is configured to receive information from a volatile organic compound sensor (TVOC) It analyzes whether the measured organic compound is a third condition that exceeds a preset threshold, and if any of the first to third conditions applies, not only does it output a notification to each lamp unit of the display lamp unit 110. , the wireless communication antenna 120 can be controlled to provide information on parameters (temperature, organic compounds, flow rate) exceeding the threshold to the external manager terminal that provided the remote control request.

3 and 4 are diagrams showing a smart remote control heater 100 according to a second embodiment of the present invention. Referring to Figures 3 and 4, the smart remote control heater 100 includes the first fuel tank 190-1 to the nth fuel tank 190-n (n is 2 or more) corresponding to the fuel tank group 190. It is formed in a parallel structure of natural numbers), and each of the first fuel tank 190-1 to the nth fuel tank 190-n (n is a natural number of 2 or more) has a flow meter 150 and a sensor module 150a. It is formed to perform data transmission and reception with the controller 180, and at least two of a plurality of are placed between each of the first fuel tank 190-1 to the nth fuel tank 190-n, and are separated from each other. A connection hose 161 is formed, and each connection hose 160 is provided with a connection injection pump capable of mutually supplying fuel in the forward direction from the first fuel tank to the second fuel tank and in the reverse direction from the second fuel tank to the first fuel tank. As (162) is formed, when a certain amount of fuel is consumed less than 20%, which is the preset critical fuel amount in the flow meter 160 of each of the first fuel tank 190-1 to the nth fuel tank 190-n, From the first fuel tank 190-1, which is relatively close to the built-in fuel pump 130, to the second to second fuel tanks 190-2 to 190-n, which are sequentially distant from the built-in fuel pump 130. An intermediate selection switch configuration may be formed in the controller 180 to pump the charged fuel.

In this way, hot air can be provided through fuel combustion through the hot air device 100a for a preset time through the plurality of fuel tank groups 190, but in case of shortage in winter when overnight work is required, an auxiliary fuel tank 200 can be connected. Then, the operation time of the hot air device 100a can be extended depending on the capacity of the auxiliary fuel tank 200.

More specifically, the controller 180 provides the terminal identification number and location information of the smart remote control heater 100 including itself to the administrator terminal according to remote connection by an external administrator terminal, and the controller 180 is equipped with Depending on the external selection of the smart remote control hot air blower 100, the hot air blower 100a can be controlled to be turned on according to a remote operation control command from an external manager terminal.

In addition, the controller 180 periodically transmits the operation on (ON) and operation off (OFF) status information of the hot air device (100a) to the administrator terminal through the network in order to notify the administrator terminal that it is controlled by the administrator terminal. By controlling the wireless communication antenna 120, it is possible to provide a function to check the operation status of the hot air blower.

The controller 180 receives the temperature information of each smart remote control heater 100 from the temperature sensor 151a of the sensor module 150a provided in the smart remote control heater 100 that is turned on, and the volatile organic compound sensor ( Organic compound concentration information from the TVOC (152a), flow rate information of each fuel tank 190 that can be formed as one or multiple fuel tanks 190 from the flow meter 150, and terminal identification number and location information of the smart remote control heater 100 in its own memory. In addition to storing it, by controlling the wireless communication antenna 120, it transmits to the manager terminal through the network and displays not only the terminal identification number and location information of the smart remote control heater 100, but also temperature, organic compounds, and oil supply amount on the manager terminal. An information confirmation function that outputs information can be provided.

The controller 180 periodically provides information to the manager terminal about integrated information including the temperature, organic compounds, and oil supply amount information of the smart remote control heater 100 that it is operating, thereby providing mobile information to the manager terminal. A regular monitoring function can be provided.

Meanwhile, in another embodiment of the present invention, the controller 180 receives not only the flow rate information for the fuel tank 190 whose fuel is exhausted, but also the flow rate information from the IoT flow meter additionally provided in the auxiliary fuel tank 200 through short-distance wireless communication. Based on communication, it is received through the wireless communication antenna 120, and when the fuel in the fuel tank 190, 190-1 to 190-n as well as the auxiliary fuel tank 200 is below a preset threshold, the smart remote control heater 100 )'s terminal identification number and location information, as well as the flow rate information of the fuel tank 190 with exhausted fuel and the flow rate information of the auxiliary fuel tank 200, as well as the auxiliary fuel if the flow rate of the fuel tank is below a preset threshold. Start time information for driving the built-in fuel pump 130 for refueling from the tank 200 to the fuel tank 190 can be output.

That is, the controller 180 controls the wireless communication antenna 120 to transmit start time information to the manager terminal through the network, thereby determining the detailed operation of the smart remote control heater 100 corresponding to the terminal identification number and location information. In addition to tracking, it is possible to provide the manager with information on whether fuel is supplied to the auxiliary fuel tank 200 and the start time of supplemental fuel refueling.

In addition, the controller 180 has an abnormality check function for the smart remote control heater 100 that is driven and controlled, and the flow rate information for each fuel tank 190 among the at least one fuel tank 190 is preset to a critical flow rate. (20 to 25%) or less than the first condition, the second condition exceeds the set heater critical temperature, or the third condition the organic compounds measured from the volatile organic compound sensor (TVOC) exceed the preset threshold. An abnormality check can be performed when the heater is operated for the first to third conditions that perform real-time analysis, and a push notification function can be provided to the administrator terminal through the network when the temperature and organic compound concentration increases and the heater operates at an abnormally high temperature.

In addition, when the fuel tank 190 included in the smart remote control heater 100 is one and the flow rate information is less than the preset critical flow rate (20 to 25%), the controller 180 controls the controller 180 among the fuel hoses 160. ), the flow rate of the fuel tank 190 corresponding to less than the critical flow rate from the auxiliary fuel tank 200 connected to the opposite end rather than the end connected to the built-in fuel pump 130 is automatically set to the optimal charging flow rate (80 to 85%). It can perform the function of charging fuel.

In addition, in another embodiment of the present invention, the controller 180 controls the number of fuel tanks included in each smart remote control heater 100 as the first to nth fuel tanks 190-1 to 190-n. Among the fuel tanks, when the flow rate information of the first fuel tank (190-1), which is first supplied to the hot air device (100a), is less than the preset critical flow rate (20 to 25%), the second fuel tank is supplied first. By checking the flow rate information of (190-2), the flow rate exceeding the critical flow rate (20 to 25%) of the next priority fuel tank 190 is supplied to the first fuel tank (190-1), which performs the first supply first. Perform, sequentially, to the 2nd to n-1th fuel tanks 190-(n-1), which are the previous fuel tanks for the 3rd to nth fuel tanks 190-n, respectively, corresponding to the next-ranked fuel tanks. In addition to performing fuel supply, fuel supply from the second to nth fuel tanks (190-2 to 190-n) to the first fuel tank (190-1) that performs the initial supply is carried out by supplying the second to nth fuel. When the tank (190-2 to 190-n) is less than the critical flow rate, the fuel hose of the smart remote control heater (100) is connected to the last connected nth fuel tank (190-n). (160) The flow rate of the first fuel tank (190-2) corresponding to less than the critical flow rate from the auxiliary fuel tank (200) connected to the opposite end rather than the end connected to the built-in fuel pump (130) of the controller (180) is optimal. The built-in fuel pump 130 is controlled to achieve a charging flow rate (80 to 85%), or the flow rates of at least two of the first to nth fuel tanks (190-2 to 190-n) are adjusted to the optimal charging flow rate ( Control of the built-in fuel pump 130 can be performed to achieve 80 to 85%).

Meanwhile, the controller 180 analyzes the image information captured by the front imaging camera 153a formed in the direction that is the target of curing, and then turns off the driving of the hot air device 100a when analyzing the curing completion. It is possible to control the refueling of the hot air device 100a from the fuel tank 190 and the refueling of the fuel tank 190 from the auxiliary fuel tank 200 using the built-in fuel pump 130.

To this end, the controller 180 can analyze the end of curing based on big data by requesting information from the image information to a big data server connected to the network.

That is, the big data server stores curing pattern information for each building material, and the controller 180 stores multiple curing pattern information for each building material, each curing pattern information tilted at a preset angle, reversed, etc. By comparing the patterns included in the image information, the end of curing can be analyzed in the image information.

The present invention can also be implemented as computer-readable code on a computer-readable recording medium. Computer-readable recording media include all types of recording devices that store data that can be read by a computer system.

Examples of computer-readable recording media include ROM, RAM, CD-ROM, magnetic tape, floppy disk, and optical data storage devices, and are also implemented in the form of a carrier wave (e.g., transmission via the Internet). It also includes

Additionally, computer-readable recording media can be distributed across computer systems connected to a network, so that computer-readable code can be stored and executed in a distributed manner. And functional programs, codes, and code segments for implementing the present invention can be easily deduced by programmers in the technical field to which the present invention belongs.

As described above, the specification and drawings disclose preferred embodiments of the present invention, and although specific terms are used, they are used only in a general sense to easily explain the technical content of the present invention and aid understanding of the invention. , it is not intended to limit the scope of the present invention. It is obvious to those skilled in the art that in addition to the embodiments disclosed herein, other modifications based on the technical idea of the present invention can be implemented.

100: Smart remote control heater
100a: hot air device
110: display lamp unit
120: wireless communication antenna
130: Built-in fuel pump
140: automatic refueling cap
150: flow meter
150a: Sensor module
160: Gas hose
170: power line
180: Controller
190: Fuel tank

Claims (4)

Hot air device (100a), indicator lamp unit (110), wireless communication antenna (120), built-in fuel pump (130), automatic refueling cap (140), flow meter (150), sensor module (150a), refueling hose (160) , a power line 170, a controller 180, and a fuel tank 190, and the refueling hose 160 supplies fuel to the automatic refueling cap 140 according to the operation of the built-in fuel pump 130 of the controller 180. It is connected in a way that transmits a In the smart remote control heater 100, which has a structure in which the auxiliary fuel tank 200 is disposed at the opposite end of the fuel hose 160, rather than the end connected to the built-in fuel pump 130 of the controller 180,
The sensor module 150a is,
It includes a temperature sensor (151a), a volatile organic compound sensor (TVOC) (152a), and a front camera (153a),
The controller 180 is,
After receiving an external remote control request through the wireless communication antenna 120 and controlling the ON of the hot air device 100a, the smart remote control hot air blower is sent from the sensor module 150a provided in the controller 180. In addition to receiving the temperature information and organic compound concentration information of (100), the flow rate information of each fuel tank (190) is acquired in real time from the flow meter (150) and stored in its own memory, and the flow rate information for each fuel tank (190) is stored in its own memory. (capacity information of fuel at a preset time stored inside the fuel tank) is less than the preset critical flow rate (threshold value for the capacity of fuel at a preset time stored inside the fuel tank) (20 to 25% of the maximum capacity inside the fuel tank) By analyzing whether it is the first condition, the second condition exceeding the set critical temperature of the heater, or the third condition where the organic compound measured from the volatile organic compound sensor (TVOC) exceeds the preset threshold, the first to third If any of the conditions are met, not only is a notification output to each lamp unit of the display lamp unit 110, but also information on parameters (temperature, organic compounds, flow rate) exceeding the threshold is provided to the external manager terminal that provided the remote control request. Controls the wireless communication antenna 120 to
It is formed in a parallel structure of the first fuel tank 190-1 to the nth fuel tank 190-n (n is a natural number of 2 or more) corresponding to the fuel tank group 190, and each first fuel tank 190 -1) to n-th fuel tanks (190-n) (n is a natural number of 2 or more) are all equipped with a flow meter 150 and a sensor module 150a to transmit and receive data with the controller 180, and each first fuel Between the tank 190-1 and the nth fuel tank 190-n, at least two or more are placed, and separate connection hoses 161 are formed between them, and each connection hose 160 contains the first fuel. By forming a connection injection pump 162 capable of supplying fuel to each other in the positive direction from the tank to the second fuel tank and in the reverse direction from the second fuel tank to the first fuel tank, each of the first fuel tanks 190-1 to n Fuel tank (190-n) When a certain amount of fuel is consumed below 20%, which is the preset critical fuel amount in each flow meter (160), the first fuel tank (190-n) is relatively close to the built-in fuel pump (130). 1), an intermediate selection switch component is formed in the controller 180 to pump fuel charged from the second to second fuel tanks 190-2 to 190-n sequentially connected to the built-in fuel pump 130,
Hot air is provided through fuel combustion through the hot air device 100a for a preset time through a plurality of fuel tank groups 190, or when the auxiliary fuel tank 200 is connected in case of shortage in winter when work is required overnight, the auxiliary fuel tank In order to extend the operation time of the hot air device (100a) according to the capacity of (200),
The controller 180 is,
According to the remote connection by an external manager terminal, the terminal identification number and location information of the smart remote control heater 100 included therein are provided to the manager terminal, and the smart remote control heater 100 equipped with the controller 180 is provided. Controls the operation of the hot air device 100a to be turned on according to a remote operation control command from an external manager terminal according to an external selection,
In order to notify the manager terminal that it is being controlled by the manager terminal, a wireless communication antenna 120 is used to periodically transmit driving on and driving off status information of the hot air device 100a to the manager terminal through the network. By controlling it, it provides a function to check the operation status of the heater,
Temperature information of each smart remote control heater 100, volatile organic compound sensor (TVOC) 152a, from the temperature sensor 151a of the sensor module 150a provided in the smart remote control heater 100 that is turned on. Organic compound concentration information from the flow meter 150, flow rate information of each fuel tank 190 that can be formed as one or multiple fuel tanks (capacity information of fuel for a preset time stored inside the fuel tank), and smart remote control heater 100. In addition to storing the terminal identification number and location information in its own memory, by controlling the wireless communication antenna 120, it is transmitted to the manager terminal through the network and the terminal identification number and location of the smart remote control heater 100 is displayed on the manager terminal. It provides an information confirmation function that outputs not only information but also temperature, organic compounds, and oil supply amount information.
By periodically providing information to the manager terminal about integrated information including the temperature, organic compounds, and oil supply amount information of the smart remote control heater 100 that the user is operating, a mobile-based monitoring function is provided for the manager terminal. Provides,
The controller 180 is,
In addition to the flow rate information for the fuel tank 190 where the fuel has been exhausted (fuel capacity information for a preset time stored inside the fuel tank), the flow rate information is received wirelessly from an IoT flow meter additionally provided in the auxiliary fuel tank 200. Based on communication, it is received through the wireless communication antenna 120, and when the fuel in the fuel tank 190, 190-1 to 190-n as well as the auxiliary fuel tank 200 is below a preset threshold, the smart remote control heater 100 )'s terminal identification number and location information, as well as the flow rate information of the fuel tank 190 with exhausted fuel and the flow rate information of the auxiliary fuel tank 200, as well as the auxiliary fuel if the flow rate of the fuel tank is below a preset threshold. Outputs start time information for driving the built-in fuel pump 130 for refueling from the tank 200 to the fuel tank 190,
The controller 180 controls the wireless communication antenna 120 to transmit start time information to the administrator terminal through the network, thereby tracking the detailed operation of the smart remote control heater 100 corresponding to the terminal identification number and location information. In addition, it provides the manager with information on whether fuel is supplied to the auxiliary fuel tank 200 and the start time of supplementary fuel refueling.
This is an abnormality check function for the smart remote control heater 100 that is driven and controlled when the heater is operated, and the flow rate information for each fuel tank 190 among at least one fuel tank 190 is preset to the critical flow rate (preset stored inside the fuel tank). The first condition is less than the critical value of the fuel capacity at a set time (20 to 25% of the maximum capacity inside the fuel tank), the second condition is more than the set critical temperature of the heater, or the temperature measured from the volatile organic compound sensor (TVOC) An abnormality check is performed when the heater is operated for the first to third conditions, which performs real-time analysis as to whether the organic compound is a third condition that exceeds a preset threshold, and when the temperature and concentration of organic compounds increases and the heater operates at a high temperature or abnormality, the network Provides a push notification function to the administrator terminal through
The controller 180 is,
If there is one fuel tank 190 included in the smart remote control heater 100, the flow rate information (capacity information of fuel at a preset time stored inside the fuel tank) is set to a preset critical flow rate (a preset time stored inside the fuel tank). (threshold for fuel capacity) (20 to 25% of the maximum capacity inside the fuel tank), the auxiliary fuel connected to the opposite end of the fuel hose 160 rather than the end connected to the built-in fuel pump 130 of the controller 180 Characterized in that it performs a function of automatically charging fuel so that the flow rate of the fuel tank 190 corresponding to less than the critical flow rate from the tank 200 is the optimal charging flow rate (80 to 85% of the maximum capacity inside the fuel tank). Smart remote control heater.
The method of claim 1, wherein the controller 180,
If the number of fuel tanks included in each smart remote control hot air blower (100) is plural, including the first to nth fuel tanks (190-1 to 190-n), the first fuel tank among each fuel tank to supply to the hot air device (100a) 1 The flow rate information (capacity information of fuel at a preset time stored inside the fuel tank) of the fuel tank 190-1 is set to a preset critical flow rate (threshold for the capacity of fuel at a preset time stored inside the fuel tank) (fuel If it is less than 20 to 25% of the maximum capacity inside the tank, the flow rate information of the second fuel tank 190-2 (capacity information of the fuel for a preset time stored inside the fuel tank), which is supplied first, is checked to determine the next priority. First supply is preferentially performed for a flow rate exceeding the preset critical flow rate of the fuel tank 190 (a threshold for the capacity of fuel at a preset time stored inside the fuel tank) (20 to 25% of the maximum capacity inside the fuel tank). supply to the first fuel tank (190-1), and sequentially supply the second to n-1 fuel tanks corresponding to the third to n-th fuel tanks (190-n) corresponding to the next priority fuel tanks. In addition to performing fuel supply to the fuel tank 190-(n-1), the second to nth fuel tanks 190-2 to 190- are supplied to the first fuel tank 190-1 for the first time. When the fuel supply in n) is less than the critical flow rate (threshold for the capacity of fuel stored inside the fuel tank for a preset time) in each of the second to nth fuel tanks (190-2 to 190-n) When completed, for the nth fuel tank (190-n) connected last, the end of the fueling hose (160) of the smart remote control heater (100) is not connected to the built-in fuel pump (130) of the controller (180). The optimal charging flow rate ( The built-in fuel pump 130 is controlled so that the maximum capacity inside the fuel tank is 80 to 85%, or the flow rate of at least two of the first to nth fuel tanks (190-2 to 190-n) is optimal. Controls the built-in fuel pump 130 to achieve a charging flow rate (80 to 85% of the maximum capacity inside the fuel tank),
The controller 180 is,
After analyzing the image information captured by the front camera 153a formed in the direction that is the target of curing, when analyzing the end of curing, the hot air device 100a is driven OFF, and the fuel tank ( Controls the interruption of refueling of the hot air device 100a from 190 and refueling from the auxiliary fuel tank 200 to the fuel tank 190 using the built-in fuel pump 130,
The controller 180 analyzes the end of curing based on big data by requesting information from the image information to a big data server connected to the network. The big data server stores curing pattern information for each building material, and the controller 180 Smart is characterized by analyzing the end of curing in the image information by comparing the plurality of curing pattern information for each building material, each curing pattern information tilted at a preset angle, and the reversed pattern included in the image information. Remote control heater.
If the number of fuel tanks included in each smart remote control hot air blower (100) is plural, including the first to nth fuel tanks (190-1 to 190-n), the first fuel tank among each fuel tank to supply to the hot air device (100a) 1 The flow rate information (capacity information of fuel at a preset time stored inside the fuel tank) of the fuel tank 190-1 is set to a preset critical flow rate (threshold for the capacity of fuel at a preset time stored inside the fuel tank) (fuel If it is less than 20 to 25% of the maximum capacity inside the tank, the flow rate information of the second fuel tank 190-2 (capacity information of the fuel for a preset time stored inside the fuel tank), which is supplied first, is checked to determine the next priority. First supply is preferentially performed for a flow rate exceeding the preset critical flow rate of the fuel tank 190 (a threshold for the capacity of fuel at a preset time stored inside the fuel tank) (20 to 25% of the maximum capacity inside the fuel tank). Supply is performed to the first fuel tank 190-1, and sequentially, the 2nd to n-1 fuel tanks are the previous fuel tanks for the 3rd to nth fuel tanks 190-n corresponding to the next-ranked fuel tanks. In addition to performing fuel supply to the fuel tank 190-(n-1), the second to nth fuel tanks 190-2 to 190- are supplied to the first fuel tank 190-1 for the first time. When the fuel supply in n) is less than the critical flow rate (threshold for the capacity of fuel stored inside the fuel tank for a preset time) in each of the second to nth fuel tanks 190-2 to 190-n. When completed, for the nth fuel tank (190-n) connected last, the end of the fueling hose (160) of the smart remote control heater (100) is not connected to the built-in fuel pump (130) of the controller (180). The optimal charging flow rate ( The built-in fuel pump 130 is controlled so that the maximum capacity inside the fuel tank is 80 to 85%, or the flow rate of at least two of the first to nth fuel tanks (190-2 to 190-n) is optimal. Controls the built-in fuel pump 130 to achieve a charging flow rate (80 to 85% of the maximum capacity inside the fuel tank),
After analyzing the image information captured by the front camera 153a formed in the direction that is the target of curing, when analyzing the end of curing, the hot air device 100a is driven OFF, and the fuel tank ( Controls the interruption of refueling of the hot air device 100a from 190 and refueling from the auxiliary fuel tank 200 to the fuel tank 190 using the built-in fuel pump 130,
The completion of curing is analyzed based on big data by requesting information from the video information to a big data server connected to the network. The big data server stores curing pattern information for each building material, and the controller 180 provides multiple information for each building material. A controller 180 that analyzes the end of curing in the image information by comparing the curing pattern information, each curing pattern information tilted at a preset angle, or the reversed pattern included in the image information with the pattern included in the image information; A smart remote control heater comprising a.
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