KR101465069B1 - a hot blast heater and boiler using heat transfering oil - Google Patents

Abstract

The present invention relates to an air heater and, more specifically, to an air heater which uses a heat transfer oil, uses a concurrent heating filling material, and has a circulation device configured to be connected to a hot air generation unit. The present invention provides an air heater including: a heating unit (100), a heat exchange unit (200), and a hot air generation unit (300). In addition, the present invention provides an air heater wherein the heating unit (200) includes: a heating container (110), a heat transfer unit (120), a concurrent heating filling material (130), a heat transfer oil (140), and a heater (150). In addition, the present invention provides an air heater wherein the hot air generation unit (300) includes: a power generation unit (310), a blower unit (320), and a circulation device (330). In addition, the present invention provides an air heater further including a casing portion (400) and a control unit (500). In addition, the present invention provides a boiler including a heating unit (100), a heat transfer unit (122), and an exhaust hot water supply unit (121). Moreover, the present invention provides a boiler wherein the heating unit includes a heating container (110), a heat transfer unit (120), a concurrent heating filling material (130), a heat transfer oil (140), and a heater (150).

Description

A hot blast heater and boiler using heat transfer oil

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hot air fan, and more particularly, to a heat medium oil fan having a technical feature in that a heat medium oil is used and a heat insulating filler is used and a circulating device is connected to a hot air generating part.

The presently used hot air fan system has a heat generating coil having a predetermined size and blows wind to the heat generating coil side to allow wind to flow to the heat generating coil side to discharge hot wind.

However, in the hot air fan system using the heat generating coil, the surrounding air is burned through the heat of the coil to generate an oxygen shortage phenomenon, and also there is a problem that it can be ignited due to foreign substances or the like.

On the other hand, since the heat generating coils are constantly heated, electric energy consumption is large, which causes electric energy shortage in winter and various types of fire accidents due to electric power overload.

The present invention relates to an improved hot air fan system for solving the above problem, which is provided with a heating oil oil storage tank of a predetermined size, heating the heating oil oil using electric energy, and repeating circulation through a circulation pipe, The blower is used to blow air to the circulation pipe side so that the air that is in contact with the circulation pipe heated through the heat medium oil is heated to discharge the hot air.

However, in such a warm air system, the rising temperature is limited depending on the nature of the heat medium oil, and since the temperature of the heat medium oil currently used is low, the temperature is lowered while circulating through the circulation pipe, There was a problem to be done.

In addition, since only electric energy is used to heat the heat medium oil, it is difficult to solve the problem of electric energy shortage due to the rapid increase in use of the hot air fan system in winter.

In order to solve the problems of the prior art described above, Patent Document 10-1016553 (a hot air system using a heating medium, hereinafter referred to as "prior art") has been proposed. As a heat medium And an air circulating unit for introducing the outside air and discharging the outside air which has been heated by the heating medium reacted with the heating medium vaporized by the heating medium heating unit to the outside, have.

The present invention also provides a heat accumulating type electric boiler for heating and hot water using heat medium oil, wherein the heat accumulating water is filled in the heat accumulating water filled with the heat medium oil and equipped with the electrothermal heater for heating the heat medium oil, A separate cylindrical heat exchanger heater is installed in a concentric circulation manner to form a double cylindrical electric boiler, and the heat is accumulated by heating the water by the heat fluid heated by the electric heater, but the heat is insufficient for the regenerative water heater And the heat pipe is connected to the hot water piping which is connected to the water supply system to heat the hot water pipe and the heating pipe as a double helical type which is opposed to each other so as to maximize the heat transfer area, Hot water is instantaneously supplied, and at the same time, the heating pipe connected to the heating pipe by heating pipe The heating water is heated by the heat medium. When the heat is insufficient, the water in the water tank is reheated by the heater for the heat quantity supplement, and the water is mixed with the water in the preheated water tank without temperature variation. This is a method to save energy by reducing the operation load of the equipment by complementary heat exchange of the complex heat source. By transferring the hot water for heating to the set temperature simultaneously with the hot water supply, it is possible to utilize environmentally friendly, energy saving heat oil, Boiler ".

The conventional hot air apparatus and the related art still require a lot of energy for heating the heat medium oil. In order to maintain a constant temperature of the heated heat medium oil, the heater is repeatedly heated or the heating is stopped There has been a problem that the energy loss is large, and the present invention provides a hot air fan for solving the problem.

In addition, the present invention provides a hot air heater that can maintain a high heat amount even by injection of energy with a low heat transfer oil by using a heat transfer filler which improves the ability to retain heat of the heat transfer oil.

Further, the present invention is circulated in a circulating pump for circulating a heat medium oil to a high temperature (more than 300 degrees Celsius) so that the heat medium oil flows out from the circulation pump and damages the motor and the reducer directly connected to the circulation pump, Even if there is a problem of ignition, I would like to provide a hot air fan to solve this problem.

In order to solve the problems of the prior art and the prior art described above,

A heat exchanger (200), and a hot air generator (300).

In the present invention, the heating unit 200 includes a heating cylinder 110, a heat transfer unit 120, a heat insulating filler 130, a heating medium oil 140, and a heater 150, Lt; / RTI >

Also, the present invention provides a hot air fan, wherein the hot air generating unit 300 includes a power generating unit 310, a blowing unit 320, and a circulating unit 330.

Also, the present invention provides a hot air fan characterized by further comprising a casing unit (400) and a control unit (500).

Also, the present invention provides a boiler including a heating unit 100, a heat transfer unit 122, and an exhausted hot water supply unit 121.

Also, the heating unit includes a heating cylinder 110, a heat transfer unit 120, a heat insulating filler 130, a heating medium oil 140, and a heater 150.
Also,
A heating medium oil filled in the heating cylinder and a heat-insulating filler,
A heater installed in the heating cylinder for heating the heating medium oil, and
And a heat transfer unit installed in the heating cylinder, the heat transfer unit including a tube formed in a coil shape to receive a heat transfer material therein;
A heat exchange unit connected to the heat transfer unit and including a heat transfer material therein to perform heat exchange;
A power generating unit for generating a rotational power,
A power-rich portion which receives rotational power from the power generating portion and generates wind by rotation,
And a circulation device connected to the heat exchange unit and receiving a rotational power from the power generation unit to rotate the impeller to circulate the heat transfer material. And
A casing unit that houses the heating unit, the heat exchanging unit, and the hot air generating unit; And,
Wherein the blower unit is installed between the power generating unit and the circulation unit,
A hot air flow port for discharging hot air to the outside of the casing portion is provided in the casing portion, the hot air flow port is provided in a casing portion closer to the power generating portion as compared with the circulation device or the airflow-
The heat-radiating filler has a specific gravity higher than that of the thermal oil, and is selected from metals, ceramics, and rocks.
Characterized in that the thermal oil is charged to 75 to 90% of the heating barrel volume
And is a hot air fan.

In the present invention, the conventional hot air device and the prior art still require a lot of energy to heat the heating oil. In order to maintain a constant temperature of the heated heating oil, the heater is continuously heated or repeatedly heated There is a lot of energy loss problem, but it creates the effect of completely solving it.

Particularly, according to the present invention, by using the heat-absorbing filler which enhances the ability to retain the heat of the heat medium oil, the high heat efficiency can be maintained by maintaining the high heat quantity even by the injection of the energy with a small amount of heat medium oil.

Further, the present invention is circulated in a circulating pump for circulating the heat medium oil by the function of a warm air generating part composed of a power generating part, a blowing part and a circulating device, so that the heat medium oil flows out from the circulating pump A motor directly connected to the circulation pump, a damper, and a failure of the fan, and even ignition.

1 is a conceptual view of a heat medium oil heat fan according to the present invention;
1B is a conceptual diagram of a hot air generator having a structure in which a hot air generating unit according to the present invention is disposed at a lower portion of a heat exchanging unit.
2 is a structural view of a heating unit of a heat medium oil heat fan according to the present invention.
3 is a structural view of a hot air generating part of a heat medium oil heat fan according to the present invention.
FIG. 3B is another embodiment of the hot air generating unit of the heat medium oil heat fan according to the present invention. FIG.
4 is a conceptual view of a wing portion of a hot air generating portion according to the present invention.
4B is another embodiment of the wing portion of the hot air generating portion according to the present invention.
5 is a conceptual view of a connecting portion of the warm air generating portion wing portion according to the present invention.
6 is a conceptual view of a boiler according to the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS FIG.

The present invention provides a hot air fan including a heating unit (100), a heat exchanging unit (200), and a hot air generating unit (300).

Also, the present invention provides a boiler including the heating unit 100, the heat transfer unit 122, and the hot water supply unit 122 described above.

The present invention also provides a fan unit having a casing unit 500 including the above-described components.

Technical features of the present invention reside in the heating unit 100 described above.

The heating unit 100 of the present invention means an apparatus or means for generating heat required to generate warm air.

The heating unit 100 of the present invention is characterized in that it includes a heating cylinder 110, a heat transfer unit 120, a heat insulating filler 130, a heating medium oil 140, and a heater 150.

As shown in FIG. 2, the heating cylinder 110 of the present invention has a cylindrical shape or a structure.

Inside the heating cylinder, a heat transfer part, a heat insulating filler, and a heat medium oil are included.

The heater 150 means an apparatus or means for generating heat. Therefore, a heat generating device using energy such as ordinary fossil fuel or electricity can be used.

The heater of the present invention generates heat to heat the above-described heat medium oil. Therefore, the temperature of the heat medium oil is increased by the heater.

The heater 150 of the present invention includes a temperature sensor 510 to control and control the temperature of the heat medium in the heating cylinder.

That is, the heating oil in the heating cylinder is set to a certain range of temperature. When the temperature of the heating cylinder falls below the set temperature, the heater operates. When the temperature of the heating cylinder rises above the set temperature, the heating operation is stopped.

Accordingly, the present invention includes a control unit 500 to perform the temperature control function of the heater.

The control unit is an ordinary device for operating, operating, and controlling the hot air fan of the present invention, and means that an information processing device such as an MCU (Micro Controller Unit), a memory, a control program, and the like are mounted.

The present invention is characterized in that the heating cylinder 110 is formed with the heat medium oil 140 and the heat-absorbing filler 130.

The thermal oil of the present invention (usually 0.4 to 0.6 cal / g ° C) has the advantage that the specific heat is lower than that of water (1 cal / g ° C), and the temperature rises at a high speed by the heater. . ≪ / RTI >

This problem is very disadvantageous in terms of energy efficiency because the heater must be continuously heated to provide the necessary warm air.

Accordingly, in order to solve the above-described problem, the present invention has been made to fill the heat medium filler 130 with the heat medium oil, so that the heat medium oil is not easily cooled.

The heat-absorbing filler (130) used in the present invention may be a metal, ceramic, or rock having a specific gravity higher than that of the heat medium oil.

Therefore, a metal ball, a ceramic ball, a rock ball, or the like can be used.

The size of the heat-insulating filler is preferably 20 to 40 mm, but is not limited thereto.

More preferably, in the present invention, it is advantageous from the economical point of view to use rock balls.

The meaning of the rock balls used in the present invention includes crushed rocks obtained from ordinary rivers and seas, and processed rocks.

Therefore, it is possible to use all kinds of volcanic rocks and sedimentary rocks such as ordinary granite, basalt, olive rock, andesite and rhyolite.

It is more preferable to use quartz with a large amount of quartz.

The present invention prevents the cooling of the heated oil by the function and the action of the above-mentioned heat-insulating filler material and assists the effect of keeping warmth faithfully.

That is, the specific heat of the heat-insulating filler is lower than that of the thermal oil (usually 0.11 cal / g ° C for iron and 0.2-0.3 cal / g ° C for rock) It has a remarkably large effect.

Accordingly, the heat transfer material is transferred to the heat medium oil during the cooling process.

With this function and action, the heat medium oil has a slow cooling effect and the heat medium oil has the effect of stably maintaining the temperature.

As the thermal oil for use in the present invention, ordinary thermal oil may be used. Therefore, mineral oil, diphenyl-diphenyl oxide, chlorinated polyphenyl, alkylbenzene and the like can be used.

The present invention is more preferably composed of a mixture of alkylbenzene and dibenzyltoluene. Further, it is preferable that the composition comprising any one of alkylbenzene and dibenzyltoluene and aromatic hydrocarbons is mixed with heat and heat holding effect It is advantageous.

The thermal oil used in the present invention exhibits the action and effect of rising to 380 degrees Celsius.

In the present invention, it is preferable that the thermal oil is filled up to a volume of about 75 to 90% of the heating cylinder.

The meaning of filling up to the volume of about 75 to 90% of the above-mentioned heating barrel is filled with 75 to 90% of the heating barrel volume together with other constitutions (for example, filler, heat transfer part, heater, etc.) included in the heating barrel Means that.

The reasons for filling the heat pipe up to a volume of 75 to 90% of the heat pipe are to prevent the breakage and explosion of the heat pipe due to the expansion of the heat medium oil and vaporization.

In the present invention, the heat transfer part 120 means a device or a device having a tube shape and a heat transfer material therein.

Therefore, it is preferable that the heat transfer part has a configuration and a shape having a wide surface area in order to ideally absorb the heat retained in the heat medium in the heating cylinder.

As shown in FIG. 2, the heat transfer part of the present invention may be a coil-shaped heat transfer part, and the heat transfer material inside the heat transfer part transfers heat to the heat exchange part 200.

In the present invention, the heat exchanger (200) is formed outside the heating cylinder.

As shown in FIG. 1, the heat exchanger is connected to the heat exchanger, and the heat exchanger includes a heat transfer material, so that heat exchange with the air inside the case is performed.

The above-described heat exchanging unit may be constituted by a normal coil shape or a radiator shape.

As described above, the heat transfer material at a high temperature of the heat transfer portion of the heating drum is transferred to the heat exchange portion, and heat exchange is performed in the heat exchange portion to generate warm air.

Therefore, the present invention requires a device for circulating a heat transfer material moving through the heat transfer part and the heat exchange part.

In the present invention, the heat transfer material may use a heating medium. Therefore, a liquid substance such as water or oil can be used.

It is more preferable to use the above-described thermal oil as the heat transfer material.

The above-mentioned thermal oil may be ordinary thermal oil. Therefore, mineral oil, diphenyl-diphenyl oxide, chlorinated polyphenyl, alkylbenzene and the like can be used.

As described above, the heat transfer material of the present invention is more preferably composed of a mixture of alkylbenzene and dibenzyltoluene. Further, the heat transfer material may be composed of any one of the alkylbenzene and the dibenzyltoluene and the aromatic hydrocarbons It is advantageous in heat generation and heat holding effect.

The technical feature of the present invention is that the circulating device 330 for circulating the heat transfer material is installed together with the hot air generating part 300, and the structure of the hot air generating part itself has a technical feature.

The hot wind generating unit 300 of the present invention includes a power generating unit 310, a blowing unit 320, and a circulating unit 330.

As shown in FIG. 3, the power generating portion refers to a device or means such as a speed reducer, a motor, or the like that generates rotational power.

The power generating unit 310 of the present invention functions to transfer rotational power to the blowing unit 320 and the circulating unit 330.

The technical feature of the present invention is that the power generation unit transmits power to the circulation device via the blower without being directly connected to the circulation device.

Conventionally, in a circulating device such as a pump circulating a heat medium oil, the power generating portion and the circulating device are directly connected to each other, and the motor, the speed reducer, etc. of the power generating portion are damaged by the heat medium oil flowing out finely from the circulating device.

Particularly, the heat medium oil circulated through the circulation pump may have a temperature of 300 degrees Celsius or higher, so that the packing material used in the circulation pump may be damaged or leaked to the rotary shaft, There has been a problem of damage to the motor, the speed reducer, etc., and short-circuiting.

Therefore, according to the present invention, the rotational power generated in the power generating unit is transmitted to the circulating unit via the blowing unit, thereby solving the problems of damage to the motor, speed reducer, .

Furthermore, the blowing unit 320 of the present invention performs a blowing action to cool the circulation pump. According to the cooling function of the circulation pump, the packing material used in the circulation pump prevents the damage due to the high temperature and prevents the swelling of the rotating shaft at high temperature, thereby preventing the leakage of the heat medium oil.

In the present invention, the above-mentioned blowing unit 320 refers to a device or means that blows air to generate wind by rotation.

As shown in FIG. 3, the blowing unit 320 includes a connecting portion 322 and a wing portion 321.

The connection portion 322 refers to a device or means that is connected to the rotation shaft of the power transmitting portion or the circulating device and also connects the wing portions to each other.

The connection part also functions to fix and support the wing part 321.

The wing portion 321 described above means an apparatus or means configured to generate wind by rotation.

3B shows another embodiment of the hot air generating unit. As shown in the figure, the blower unit includes the blade unit 321 and the connecting unit 322.

The blowing portion shown in FIG. 4 shows one wing portion 321 and the connecting portion 322 is connected to the power transmitting portion or the rotating shaft of the circulating device, respectively.

The wing portion is configured in a shape, structure, or screw shape or structure that rotates in a direction perpendicular to the rotation axis.

When the wing portion is rotated by the configuration of the wing portion, wind is generated in the direction of the rotation axis.

As shown in FIG. 4B, it is preferable that the blades have a concave shape when the blades 321 are connected to the connecting portions 322, and concave shapes are formed in the same direction when the blades are connected to the connecting portions.

The effect of increasing the wind power by the wings of this structure is also shown.

As shown in FIG. 5, a shaft connecting hole 323 is formed in the connecting portion 322, and is connected to the rotating shaft of the motor and to the rotating shaft of the circulating pump.

In addition, the connecting portion has a space formed in the center thereof, so that the possibility that the heat medium oil flowing out from the circulation pump is transmitted to the motor, which is the power generating portion, is largely excluded.

That is, as shown in FIG. 4B, since a plurality of impellers of the wing portion are connected to the connecting portion without a separate shaft, and the rotational power is transmitted by the plurality of impellers, the flow of the heat medium oil flowing out from the circulating pump is blocked, It acts to exclude the possibility of being transmitted to the motor as a generator.

The wing portion is preferably located close to the heat exchanging portion so that it is easy to discharge the heat generated in the heat exchanging portion.

For this reason, as shown in FIG. 1, the hot-air generating unit 300 is positioned above the heat-exchanging unit.

In another embodiment of the present invention, hot air is generated very efficiently even when the hot air generating part 300 is positioned below the heat exchanging part 200.

As shown in FIG. 1B, even if the hot air generating part 300 of the present invention is positioned below the heat exchanging part 200, the hot air can be easily discharged to the hot air blowing port 520 of the casing part by the convection phenomenon of hot air.

As shown in FIG. 3, depending on the size of the hot air fan, a plurality of the fan-shaped portions may be formed, so that the connecting portion 322 also functions to connect the fan portion and the fan portion.

The circulator 330 of the present invention is connected to the heat exchanger and includes a heat medium oil inflow portion 331 and a heat medium oil outflow portion 332.

The circulation device described above is economically preferable in that the impeller is rotated to circulate the heat medium oil, but the present invention is not limited thereto.

The casing unit 500 of the present invention means an apparatus or means including the above-mentioned components and functioning to prevent external physical force or the like.

The casing portion of the present invention is provided with a hot air vortex 520.

The hot air vent 520 of the casing unit means an apparatus or means for discharging hot air generated by the above-described hot air generating unit.

As shown in Fig. 1, the hot wind is formed on the axis of the blowing portion of the hot wind generating portion, so that generated hot wind can be easily discharged.

The present invention provides a heat medium oil heat fan having the above-described structure and function.

Further, the present invention provides a boiler including the heating unit 100, the heat transfer unit 122, and the exhaust hot water supply unit 121 as described above.

As shown in FIG. 6, the heating unit 100 includes a heating cylinder 110, a heater 150, a heating medium oil 140, and a heat-insulating filler 130.

The configurations of the heating unit are as described above.

In the boiler of the present invention, the heater 150 is formed in a heating cylinder, and the periphery thereof is formed so as to surround the heat transfer part 122.

With this structure, the heat transfer ability from the heater to the heat transfer part is significantly increased.

The heat transfer part 122 functions to supply hot water to the room for heating.

Therefore, the hot water inlet pipe 122-1 and the hot water outlet pipe 122-2 are connected to the seawater desalination unit, so that the hot water continues to circulate.

The exhaust hot water supply unit 121 of the boiler of the present invention means an apparatus or means for performing the function of supplying hot water to be exhausted such as shower,

The exhaustion hot water supply unit 121 of the present invention is a technical feature in that it is formed in the form of a coil in the form of a coil on the side surface of the heating cylinder.

In this type of coil, it is formed on the side surface of the heating cylinder in the shape of ice, thereby significantly increasing the hot water capacity of the coil-shaped exhaust hot water supply unit, and thus it is possible to actively and effectively supply hot water even when the hot water consumption is large.

With this function, the capacity of the heating cylinder is different according to the size of the heating cylinder. However, even when the capacity of the heating cylinder is about 40 to 100 liters, the capacity for providing hot water of about 20 to 40 liters is obtained.

Therefore, the exhaust hot water supply unit 121 is connected to the exhaust hot water inflow pipe 121-1 and the exhaust hot water outflow pipe 121-2.

With this configuration, the water supplied from the exhaust hot water inflow pipe is heated in the exhaust hot water supply unit, and hot water can be supplied through the exhaust hot water discharge pipe.

The present invention provides a boiler that maximizes energy efficiency due to the functions of the thermal oil 140 and the heat-trapping filler 130 as described above.

The present invention is a very useful invention for industries that produce, manufacture, process, distribute and sell hot air fans and boilers.

Particularly, the present invention is an extremely useful invention for an industry that produces, manufactures, processes, distributes and sells hot air fans and boilers using thermal oil.

100: heating section 110: heating tube
120: heat transfer part 121: exhaust hot water supply part
121-1: exhaust hot water inlet pipe 121-2: exhaust hot water outlet pipe
122: Heat transfer part of the boiler 122-1 Heating hot water inflow pipe
122-2: Heating hot water outlet pipe
130: Heat-insulating filler
140: heat medium oil 150: heater
200: Heat exchanger
300: Hot air generating unit 310: Power generating unit
320: a blown part 321: a wing part
322: connection part 330: circulation device
400:
500: control unit 510: temperature sensor
520: Hot air blow

Claims (6)

Heating cylinder,
A heating medium oil filled in the heating cylinder and a heat-insulating filler,
A heater installed in the heating cylinder for heating the heating medium oil, and
And a heat transfer unit installed in the heating cylinder, the heat transfer unit including a tube formed in a coil shape to receive a heat transfer material therein;
A heat exchange unit connected to the heat transfer unit and including a heat transfer material therein to perform heat exchange;
A power generating unit for generating a rotational power,
A power-rich portion which receives rotational power from the power generating portion and generates wind by rotation,
And a circulation device connected to the heat exchange unit and receiving a rotational power from the power generation unit to rotate the impeller to circulate the heat transfer material. And
A casing unit that houses the heating unit, the heat exchanging unit, and the hot air generating unit; And,
Wherein the blower unit is installed between the power generating unit and the circulation unit,
A hot air flow port for discharging hot air to the outside of the casing portion is provided in the casing portion, the hot air flow port is provided in a casing portion closer to the power generating portion as compared with the circulation device or the airflow-
The heat-radiating filler has a specific gravity higher than that of the thermal oil, and is selected from metals, ceramics, and rocks.
Characterized in that the thermal oil is charged to 75 to 90% of the heating barrel volume
Hot air fan
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