KR102638763B1 - Hot air blower using radiater - Google Patents

Abstract

The heater using a radiator of the present invention includes: a radiator in which heated water is supplied to the inlet and heat is generated through a process in which the supplied water is circulated and then discharged to the outlet; a blower installed in front of the radiator to suck in outside air through the radiator and discharge the sucked air into the room; A heater that receives water discharged from the outlet of the radiator, heats it, and outputs water; It includes a pump that supplies heated water from the heater to the radiator. In this embodiment of the present invention, air introduced from the outside can be heated by passing through a radiator, and the heated hot air can be discharged through a blower.

Description

Hot air blower using radiator}

The present invention relates to a hot air blower using a radiator, and more specifically, to a hot air blower using a radiator that passes air introduced from the outside through a radiator, heats it, and discharges it as hot air through a blower.

The content described below simply provides background information related to the present invention and does not constitute prior art.

In general, temperature and humidity control in cultivation facilities or breeding grounds is a key factor in determining the income of the farm when raising crops or livestock.

Accordingly, various types of cooling/heating technologies have been disclosed, including those that maintain a constant temperature distribution by removing moisture or forcibly circulating indoor air, as well as cooling and heating.

As devices for heating the interior of greenhouses, agricultural heaters equipped with burners or boilers with various characteristics that selectively use briquettes, charcoal, lignite, coke, etc. are used. In addition, insulating fabrics such as cotton or non-woven fabrics are used. A system that can open and close it manually or automatically is also applied.

However, the conventional heater or boiler described above has low profitability because it uses expensive oil, and when waste wood or briquettes are used, not only is it very inconvenient to maintain, but it also has disadvantages such as a significant decrease in heating efficiency, and is used only for heating. Therefore, it has the disadvantage of not being able to be used in the summer when the temperature rises significantly.

In other words, conventional greenhouse heating/heating devices have the problem that fuel costs are excessive, and especially when expensive oil or fuel costs are incurred, production costs are relatively high and competitiveness is reduced.

In addition, crop cultivation houses such as glass greenhouses or plastic greenhouses are installed to grow horticulture or fruit trees in spring, fall, or winter when the outside temperature is low, and heating is essential to maintain an appropriate indoor temperature.

In order to heat the interior of a conventional crop cultivation house, warm air heated by a boiler is blown into the inside of the house through a blowing duct installed on the floor inside the house, or water rapidly heated by a boiler is installed inside the house. A method was taken to heat the indoor air by supplying it to the heating part.

Conventional house heating devices have the disadvantage that the combustion-type boiler is not easy to install and move, and its configuration is complicated, resulting in a large overall size of the device. Since it uses oil as a raw material, the operating cost per area is high, and due to the nature of the boiler, the inside of the house is large. There were problems with energy waste and low thermal efficiency due to air heating.

These heating devices using oil have the disadvantage of generating soot, and in light of the current era of high oil prices, there is a problem of significant energy waste and unnecessary expenditure.

On the other hand, if there are bacteria or viruses in the air, not only the bad smell but also various bacteria proliferate, and if these bacteria are inhaled through the respiratory tract, it can cause pneumonia in severe cases and lead to Legionnaires' disease caused by Legionella bacteria, which has a mortality rate of about 25%. You can. Additionally, recently, people can contract infectious diseases due to viruses such as coronavirus.

Republic of Korea Patent No. 10-1667624

The problem to be solved by the present invention is to solve the above-mentioned problems, and is to provide a hot air blower using a radiator that heats air introduced from the outside through a radiator and discharges the heated hot air through a blower.

In addition, the problem to be solved by the present invention is to solve the above-mentioned problems, and the radiator heats the air introduced from the outside through the radiator to achieve the indoor temperature desired by the user, and discharges the heated hot air through the blower. It provides a hot air blower using .

In addition, the problem to be solved by the present invention is to solve the above-mentioned problems, and is to provide a hot air blower using a radiator that controls the hot air temperature according to the user's selection and provides comfortable heating.

In addition, the problem that the present invention aims to solve is to solve the above-mentioned problem. When bacteria or viruses harmful to the human body are detected, the temperature of the radiator is raised to the death temperature of the virus or bacteria, and then the air flowing in from the outside is blown through the radiator. It provides a heat gun using a radiator that kills viruses and bacteria by passing them through.

In addition, the problem to be solved by the present invention is to solve the above-mentioned problems, by increasing the radiator temperature to the death temperature of viruses or bacteria and stopping operation to protect the human body when a human body is detected within a predetermined distance while hot air is generated. It provides a hot air blower using .

In addition, the problem that the present invention aims to solve is to solve the above-mentioned problems, by increasing the radiator temperature to the death temperature of viruses or bacteria, and spraying disinfectant if bacteria or viruses harmful to the human body are detected even after a predetermined period of time during hot air generation. The aim is to provide a hot air blower using a radiator.

A heater using a radiator according to the characteristics of the present invention to solve these problems,

A radiator in which heated water is supplied to the inlet and heat is generated through a process in which the supplied water is circulated and then discharged to the outlet;

a blower installed in front of the radiator to suck in outside air through the radiator and discharge the sucked air into the room;

A heater that receives water discharged from the outlet of the radiator, heats it, and outputs water;

It includes a pump that supplies heated water from the heater to the radiator.

a water tank installed adjacent to the heater to supplement the shortfall of water circulating through the radiator;

a heater temperature sensor that measures the temperature of water in the heater;

Indoor temperature sensor that measures indoor temperature;

An input unit for setting the target room temperature and circulating water temperature;

It further includes a control unit that drives the heater, pump, and blower to maintain the target indoor temperature at the circulating water temperature set in the input unit.

Further comprising a bacterial detection unit for detecting bacteria or viruses harmful to the human body,

When bacteria or viruses harmful to the human body are detected by the bacteria detection unit, the control unit increases the temperature of the water in the heater to the killing temperature of the viruses or bacteria and then passes air introduced from the outside through the radiator to kill the viruses or bacteria. .

The control unit increases the temperature of the water in the heater to the death temperature of viruses or bacteria, and when a human body is detected within a predetermined distance while hot air is generated, the heater stops operating to protect the human body.

It further includes a disinfectant spray unit that sprays a disinfectant solution to kill bacteria or viruses harmful to the human body,

The control unit increases the temperature of the water in the heater to the death temperature of viruses or bacteria, and if bacteria or viruses harmful to the human body are detected even after a predetermined period of time during hot air generation, the control unit controls the disinfectant spray unit to spray the disinfectant solution.

In an embodiment of the present invention, a hot air blower using a radiator can be provided that heats air introduced from the outside through a radiator and discharges heated hot air through a blower.

In addition, in an embodiment of the present invention, a heat blower using a radiator can be provided, which heats air introduced from the outside through a radiator to achieve the indoor temperature desired by the user and discharges the heated hot air through the blower.

Additionally, in an embodiment of the present invention, it is possible to provide a hot air blower using a radiator that controls the hot air temperature by controlling the radiator temperature according to user selection, thereby providing comfortable heating.

In addition, in an embodiment of the present invention, when bacteria or viruses harmful to the human body are detected, the radiator temperature is raised to the death temperature of the viruses or bacteria, and then the air introduced from the outside is passed through the radiator to kill the viruses or bacteria. A hot air blower using can be provided.

In addition, in an embodiment of the present invention, a hot air blower using a radiator can be provided that increases the radiator temperature to the death temperature of viruses or bacteria and stops operation to protect the human body when a human body is detected within a predetermined distance while hot air is generated.

In addition, in an embodiment of the present invention, a hot air blower using a radiator can be provided that increases the radiator temperature to the death temperature of viruses or bacteria and sprays a disinfectant when bacteria or viruses harmful to the human body are detected even after a predetermined time during hot air generation. there is.

Figure 1 is a diagram showing the appearance of a heat gun using a radiator according to an embodiment of the present invention.
Figure 2 is a diagram showing a portion of the interior of a heat gun using a radiator according to an embodiment of the present invention.
Figure 3 is a block diagram of a heat gun using a radiator according to an embodiment of the present invention.
Figure 4 is a diagram showing the air flow of a heater using a radiator according to an embodiment of the present invention.

Below, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention. However, the present invention may be implemented in many different forms and is not limited to the embodiments described herein. In order to clearly explain the present invention in the drawings, parts that are not related to the description are omitted, and similar parts are given similar reference numerals throughout the specification.

In the whole, when a part "includes" a certain component, this means that it does not exclude other components, but may further include other components, unless specifically stated to the contrary.

Figure 1 is a view showing the exterior of a heat gun using a radiator according to an embodiment of the present invention, Figure 2 is a view showing a portion of the interior of a heat gun using a radiator according to an embodiment of the present invention, and Figure 3 is an implementation of the present invention. This is a block diagram of a hot air blower using a radiator according to an example, and Figure 4 is a diagram showing the air flow of a hot air blower using a radiator according to an embodiment of the present invention.

Referring to Figures 1 to 4, a heat gun using a radiator according to an embodiment of the present invention,

An air intake port 101 is formed at the rear, and the hot air blower main body 100 is made of a cylinder;

A radiator 120 installed on the front of the heater main body 100, which supplies heated water to the inlet and generates heat through the process of circulating and then discharging the supplied water to the outlet;

A blower 110 installed at the front of the radiator 120 to suck in external air through the radiator 120 and discharge the sucked air into the room;

A heater 160 that receives water discharged from the outlet of the radiator 120, heats it, and outputs water;

It includes a pump 150 that supplies heated water from the heater 160 to the radiator 120.

If necessary, the pipe connected to the inlet of the radiator 120 may be equipped with a thermostat to circulate water when the temperature exceeds 60 to 80 degrees Celsius.

A water tank 140 installed adjacent to the heater 160 to supplement the shortfall of water circulating to the radiator 120;

A heater temperature sensor 191 that measures the temperature of water in the heater 160;

Indoor temperature sensor 192 that measures indoor temperature;

An input unit 180 for setting the target indoor temperature and circulating water temperature;

It further includes a control unit 170 that drives the heater 160, water tanks 140, 150, and blower 110 to maintain the target indoor temperature at the circulating water temperature set in the input unit 180.

It further includes a bacteria detection unit 193 for detecting bacteria or viruses harmful to the human body,

When bacteria or viruses harmful to the human body are detected by the bacteria detection unit, the control unit 170 increases the temperature of the water in the heater 160 to the death temperature of the viruses or bacteria and then directs air introduced from the outside into the radiator 120. It kills viruses and bacteria by passing through it.

It further includes a human body detection unit 194 that senses the human body,

The control unit 170 increases the temperature of the water in the heater 160 to the death temperature of viruses or bacteria, and stops the operation of the heater to protect the human body when a human body is detected within a predetermined distance while hot air is generated.

It further includes a disinfectant spray unit 111 that sprays a disinfectant solution to kill bacteria or viruses harmful to the human body,

The control unit 170 increases the temperature of the water in the heater 160 to the death temperature of viruses or bacteria, and controls the disinfectant spray unit 111 when bacteria or viruses harmful to the human body are detected even after a predetermined time during hot air generation. Then spray the disinfectant solution.

It further includes a terpene scent spraying unit 112 that stores and sprays the terpene scent,

The control unit 170 sprays the disinfectant solution and then sprays the terpene scent to create a pine scent. The disinfectant spray time is 10 seconds to 1 minute, and the terpene scent spray time is 5 to 30 seconds to replace the smell of the disinfectant with the scent of pine so that you can feel the scent of pine indoors.

The disinfectant spray unit 111 and the terpene scent spray unit 112 are located at the top of the blower 110, and are set in the same blowing direction as the blower 110 to quickly and evenly spread the disinfectant and pine scent into the room.

The hot air base body 100 is formed with an air passage 130 from the inlet 101 to the radiator 120. The air passage is formed in a shape that gradually increases from the inlet 101, and the inside of the air passage is formed in the form of a screw thread. As air sucked in from the outside passes through a number of gaps in the radiator 120 along the inner surface of the air passage, hot air is generated.

The operation of the heater 100 using the radiator 120 according to an embodiment of the present invention having this configuration will be described as follows.

First, the user operates the input unit 180 to set the target indoor temperature and circulating water temperature. If necessary, the indoor target temperature can be automatically set to 25 degrees Celsius and the circulating water temperature can be set to 60 degrees Celsius. Here, the temperature of the circulating water can be set by the user between 50 degrees Celsius and 80 degrees Celsius, and in sterilization mode, it can be automatically set to 100 degrees Celsius.

Then, the control unit 170 operates the heater 160 to heat the water. Then, the pump 150 is operated to circulate water to the radiator 120.

In the radiator 120, heated water is supplied through the inlet, and the supplied water is circulated and discharged to the outlet to generate heat.

Then, the discharged water is fed back to the heater 160 and heated.

Meanwhile, the control unit 170 receives the temperature of the water in the heater 160 from the heater temperature sensor 191, drives the heater 160 until the target circulating water temperature is reached, and when the target circulating water temperature reaches the heater ( 160) Stop possible. And when the target circulating water temperature drops by about 5 degrees, the heater 160 is started again.

On the other hand, referring to FIG. 4, the control unit 170 drives the blower 110, and after air is sucked in through the external intake port 101, it flows through a plurality of gaps in the radiator 120 along the inner surface of the air passage. As it passes through, hot air is generated.

Additionally, the control unit 170 receives the indoor temperature from the indoor temperature sensor 192 and drives the pump 150 and blower 110 until the indoor temperature reaches the target indoor temperature.

And when the target indoor temperature is reached, the control unit 170 stops operating the heater 160, pump 150, and blower 110, and when the target indoor temperature drops by about 5 degrees, the controller 170 turns on the heater 160 and pump 150 again. ) and the blower (110) are operated.

On the other hand, the control unit 170 receives detection information about bacteria or viruses harmful to the human body from the bacteria detection unit 193 (193).

In addition, when bacteria or viruses harmful to the human body are detected by the bacteria detection unit 193, the control unit 170 increases the temperature of the water in the heater 160 to 70 to 100 degrees Celsius, which is the killing temperature of viruses or bacteria. Afterwards, the pump 150 and the blower 110 are operated to pass air introduced from the outside through the radiator 120 to kill viruses or bacteria.

At this time, the control unit 170 receives whether a human body is detected from the human body detection unit 194, and increases the temperature of the water in the heater 160 to the death temperature of viruses or bacteria, so that the human body is detected within a predetermined distance of 1 to 2 m while hot air is generated. When detected, the blower 110 stops operating to protect the human body.

On the other hand, the control unit 170 increases the temperature of the water in the heater 160 to the death temperature of viruses or bacteria to prevent harmful bacteria or viruses from continuing to harm the human body even after a predetermined time of about 10 minutes during hot air generation. When a predetermined amount, which is a standard level, is detected, the disinfectant spray unit 111 is controlled to spray the disinfectant solution.

Additionally, the control unit 170 sprays the terpene scent after spraying the disinfectant solution so that the user can feel the pine scent. The disinfectant spray time is 10 seconds to 1 minute, and the terpene scent spray time is 5 to 30 seconds to replace the smell of the disinfectant with the scent of pine so that you can feel the scent of pine indoors.

In the above process, the control unit 170 receives whether a human body is detected from the human body detection unit 194 even while spraying disinfectant, and stops spraying disinfectant to protect the human body when a human body is detected within a predetermined distance of 1 to 2 meters.

In an embodiment of the present invention, air introduced from the outside can be heated by passing through a radiator, and the heated hot air can be discharged through a blower.

Additionally, in an embodiment of the present invention, air introduced from the outside can be heated by passing through a radiator to achieve the indoor temperature desired by the user, and the heated hot air can be discharged through a blower.

Additionally, in an embodiment of the present invention, the radiator temperature can be controlled according to the user's selection, and the hot air temperature can be controlled to provide comfortable heating.

Additionally, in an embodiment of the present invention, when bacteria or viruses harmful to the human body are detected, the radiator temperature is raised to the virus or bacteria killing temperature, and then air introduced from the outside is passed through the radiator to kill the viruses or bacteria. .

In addition, in an embodiment of the present invention, the radiator temperature can be raised to the death temperature of viruses or bacteria, and when a human body is detected within a predetermined distance while hot air is generated, the operation can be stopped to protect the human body.

Additionally, in an embodiment of the present invention, the radiator temperature can be increased to the death temperature of viruses or bacteria, and if bacteria or viruses harmful to the human body are detected even after a predetermined period of time during hot air generation, a disinfectant can be sprayed.

As described above, specific embodiments of the present invention have been described in detail, and the spirit and scope of the present invention are not limited to these specific embodiments, but various modifications and variations are possible without changing the gist of the present invention. Those of ordinary skill in the art to which the present invention pertains will understand.

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

Claims (7)

An air intake port is formed at the rear, and the hot air base body is made of a cylinder;
A radiator installed on the front of the heater main body, supplying heated water to the inlet and generating heat through a process in which the supplied water is circulated and then discharged to the outlet;
a blower installed in front of the radiator to suck in outside air through the radiator and discharge the sucked air into the room;
A heater that receives water discharged from the outlet of the radiator, heats it, and outputs water;
It includes a pump that supplies heated water from the heater to the radiator,
a water tank installed adjacent to the heater to supplement the shortfall of water circulating through the radiator;
a heater temperature sensor that measures the temperature of water in the heater;
Indoor temperature sensor that measures indoor temperature;
An input unit for setting the target room temperature and circulating water temperature;
It further includes a control unit that drives the heater, pump, and blower to maintain the target indoor temperature at the circulating water temperature set in the input unit,
Further comprising a bacterial detection unit for detecting bacteria or viruses harmful to the human body,
When bacteria or viruses harmful to the human body are detected by the bacteria detection unit, the control unit increases the temperature of the water in the heater to the killing temperature of the viruses or bacteria and then passes air introduced from the outside through the radiator to kill the viruses or bacteria. ,
The control unit increases the temperature of the water in the heater to the death temperature of viruses or bacteria and stops the heater operation to protect the human body when a human body is detected within a predetermined distance while hot air is generated.
It further includes a disinfectant spray unit that sprays a disinfectant solution to kill bacteria or viruses harmful to the human body,
The control unit increases the temperature of the water in the heater to the death temperature of viruses or bacteria, and if bacteria or viruses harmful to the human body are detected even after a predetermined period of time during hot air generation, the control unit controls the disinfectant spray unit to spray the disinfectant solution,

It further includes a terpene scent spraying unit that stores and sprays the terpene scent,
The control unit sprays the disinfectant and then sprays the terpene scent to feel the pine scent,
The disinfectant spray time is 10 seconds to 1 minute, and the terpene scent spray time is 5 seconds to 30 seconds to replace the smell of the disinfectant with pine scent so that you can feel the pine scent indoors.
The disinfectant solution spraying unit and the terpene scent spraying unit are located at the top of the blower, and are set in the same direction as the blowing direction of the blower so that the disinfectant solution and pine scent are quickly and evenly spread throughout the room,
The hot air base body is formed with an air passage from the intake port to the radiator. The air passage is formed in a shape that gradually increases from the intake port, and the inside of the air passage is formed in the form of a screw thread so that air sucked in from the outside flows through the radiator along the inner side of the air passage. Characterized by the generation of hot air as it passes through a number of gaps.
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