KR20140122951A - powder coating - drying system using far infrared sheath heater. - Google Patents

Abstract

The present invention relates to a powder coating drying system using a far-infrared sheath heater and, more specifically, to a powder coating drying system using a far-infrared sheath heater using electricity, which is capable of reducing environmental pollution by reducing energy costs remarkably and minimizing the generation of carbon dioxide in the era of high oil prices and under a low-carbon economy system, is capable of improving the quality of a product, is capable of securing industrial safety by minimizing the dangers of a fire and an explosion, and is capable of performing a large amount of drying works.

Description

{Powder coating - drying system using far infrared sheath heater.

The present invention relates to a powder coating and drying system using far-infrared rays, and more particularly, to a powder coating and drying system using a far-infrared sheath heater using electricity, thereby remarkably reducing energy costs under an oil price era and low- Ray shielding heater using a far infrared ray sheath heater capable of minimizing environmental pollution, enhancing product quality, minimizing the risk of fire and explosion in an industrial site to ensure industrial safety, and enabling mass production.

Powder coating is a method of pretreating an object to be coated and then spraying it with powder particles having particle size and specific gravity suitable for electrostatic painting and drying in a drying furnace at a temperature of 180 ° C for 20 minutes, It melts to become a liquid, and when it reaches the temperature in the air, it becomes hardened, and it is a coating method in which the object to be coated obtains a coating film.

In this case, since the drying method of the drying furnace is mostly a method of drying with diesel or gas using hot air, the drying cost is excessive in the recent high oil price era, and it is harmful to the environment due to a large amount of carbon dioxide, Method.

On the other hand, a drying apparatus is collectively referred to as a device for removing moisture and the like contained in an object by consuming a large amount of energy such as light oil, gas, and electricity.

The most important thing in drying equipment is to dry the drying material which is the material of the finished product so that the drying result has a quality suitable for the production of the finished product. Drying of such drying material is the most important factor in drying of the drying material, such as chemical, food, fiber, paper, The variety of drying equipment is also very diverse.

Therefore, the design and manufacture of the drying equipment should take into account the characteristics of the material to be dried and it is a device that uses a large amount of energy due to the characteristics of the drying device. Therefore, energy conservation, automation, environment friendliness, .

Therefore, in the conventional drying apparatus using hot gas or gas, there are many problems such as excessive drying cost due to the use of light oil and gas, environmental pollution due to generation of carbon dioxide, deterioration of quality due to dust generation, By proposing and distributing a powder coating drying system using a far infrared ray sheath heater using electricity, it is possible to dramatically reduce the energy cost under the global oil price era and the low carbon economy system as now and reduce the pollution by minimizing the generation of carbon dioxide, Ensure industrial safety by minimizing fire and explosion hazards in industrial sites.

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SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a powder coating and drying system using a far infrared ray sheath heater using electricity, , Minimizing the generation of carbon dioxide to reduce environmental pollution, improve product quality, minimize fire and explosion risk in industrial sites, and ensure industrial safety.

Another object of the present invention is to provide a powder coating drying system, which can provide a mass drying effect, thereby shortening the drying time and maximizing the production efficiency.

In order to achieve the object of the present invention,

In the powder coating and drying system using the far infrared ray sheath heater according to an embodiment of the present invention,

A temperature sensing sensor 800 installed in the drying section in which the drying means is installed and sensing the temperature;

An air circulation fan 850 installed in the drying section where the drying means is installed to circulate air to maintain a uniform temperature throughout the entire drying section;

A central control means (900) for controlling the conveying means and the cooling means, controlling the drying temperature and the drying time of the drying subject to be dried, and controlling the power supplied to the drying means;

A conveying means 1100 for conveying the object 10 to be dried to the drying means and conveying the dried object to be dried to the cooling means again;

At least one sheath heater is installed at a predetermined interval, and drying means 1000 for drying the object to be dried by generating heat and far infrared rays when power is supplied;

And a cooling unit 1200 for cooling the object to be dried when the object to be dried that is dried by the drying unit is provided by the conveying unit.

As described above, in the powder coating drying system using the far-infrared ray sheath heater according to the present invention,

By using the powder coating drying system using the far infrared ray sheath heater using electricity, it is possible to dramatically reduce the energy cost under the oil price era and low carbon economy system, reduce the environmental pollution by minimizing the generation of carbon dioxide, improve the product quality, Thereby minimizing the risk of explosion and securing industrial safety.

In addition, it is possible to heat and dry all the objects to be dried, from powder coating drying to electrical and electronic parts, power plant parts, ship parts and agricultural and marine products, with a low energy and efficient process to obtain the best drying quality, Which can be easily set up.

In addition, the present invention provides a powder coating and drying system to provide an effect of mass drying, thereby shortening the drying time and maximizing the production efficiency.

FIG. 1 is an overall configuration diagram of a powder coating and drying system using a far infrared ray sheath heater according to an embodiment of the present invention.
FIG. 2 is a conceptual diagram schematically showing the overall configuration of a powder coating and drying system using a far infrared ray sheath heater according to an embodiment of the present invention.
3 is a block diagram of a central control means of a powder coating and drying system using a far infrared ray sheath heater according to an embodiment of the present invention.
4 is a block diagram of a cooling means of a powder coating drying system using a far infrared ray sheath heater according to an embodiment of the present invention.
FIG. 5 is a diagram illustrating the construction of drying means of a powder coating drying system using a far infrared ray sheath heater according to an embodiment of the present invention.
6 is a schematic view of a sheath heater of a powder coating drying system using a far infrared ray sheath heater according to an embodiment of the present invention.

According to an aspect of the present invention, there is provided a powder coating and drying system using a far infrared ray sheath heater,

A temperature sensing sensor 800 installed in the drying section in which the drying means is installed and sensing the temperature;

An air circulation fan 850 installed in the drying section where the drying means is installed to circulate air to maintain a uniform temperature throughout the entire drying section;

A central control means (900) for controlling the conveying means and the cooling means, controlling the drying temperature and the drying time of the drying subject to be dried, and controlling the power supplied to the drying means;

A conveying means 1100 for conveying the object 10 to be dried to the drying means and conveying the dried object to be dried to the cooling means again;

At least one sheath heater is installed at a predetermined interval, and drying means 1000 for drying the object to be dried by generating heat and far infrared rays when power is supplied;

And a cooling unit 1200 for cooling the object to be dried when the object to be dried that is dried by the drying unit is provided by the conveying unit.

At this time, the central control means (900)

A power supply controller 910 for controlling the power supply according to the temperature according to the section with reference to the temperature value sensed by the temperature sensor,

An overheat preventing unit 920 for shutting off the power supply when the set threshold value is exceeded,

An air circulation fan operation unit 930 for sending an operation signal to the air circulation fan when a temperature value detected by the temperature detection sensor is exceeded and a preset threshold value is exceeded,

A drying condition obtaining unit 940 for obtaining the set drying condition,

The material information of the allowable temperature, the allowable power density, and the allowable drying speed, which are the drying conditions obtained by the drying condition obtaining unit, and the data setting information of the temperature control, the power control schedule setting, the file name, A drying characteristic database 950 for storing the drying characteristics,

A control condition acquisition unit 960 for acquiring a mode set by the user,

A control mode obtaining unit 970 for obtaining a control mode set by the user when the mode obtained by the control condition obtaining unit is an automatic mode,

A conveying means operation portion 980 for controlling the operation of the conveying means,

And a cooling unit operating unit 990 for controlling the operation of the cooling unit.

At this time, the drying means (1000)

A sieve heater 100 connected to the power source and generating heat when power is supplied,

An enclosed type explosion-proof terminal box 200 for connecting the electric wire inserted through the electric wire inserting port to the sheath heater and constituting the terminal box cover part on the other side to block the explosion risk by the electric spark,

A hermetic type wire inlet portion 210 for hermetically pulling a wire inserted into the wire insertion port to block an explosion by an electric spark,

A reflector 400 for preventing breakage of the sheath heater and for maximizing heat efficiency by reflecting heat generated from the sheath heater,

And a protection net 410 formed on one side of the reflection plate to protect the sheath heater,

The sheath heater (100)

As far-infrared radiation ceramic coated heaters,

A sheath heater unit 110 that generates heat when power is supplied thereto,

A ceramic packing part 120 for sealing a connection part at one end of the sheath heater part,

A coupling part 130 for coupling with the enclosed type explosion-proof terminal box,

An insulator 140 configured to be insulated at one side of the fastening part,

 And a terminal unit 150 for connecting to the terminal of the electric wire.

At this time, the cooling means 1200,

An object detection sensor 1210 for detecting the entry of the object to be dried,

A detection signal providing unit 1220 for providing the detection signal to the central control unit when the object is detected by the object detection sensor,

And a cooling fan 1230 operated when receiving an operation signal transmitted from the central control unit.

At this time, the conveying means 1100,

And is a conveyor.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a powder coating and drying system using a far infrared ray sheath heater according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is an overall configuration diagram of a powder coating and drying system using a far infrared ray sheath heater according to an embodiment of the present invention.

As shown in FIG. 1, in a powder coating and drying system using a far infrared ray sheath heater according to an embodiment of the present invention,

A temperature sensing sensor 800 installed in the drying section in which the drying means is installed and sensing the temperature;

An air circulation fan 850 installed in the drying section where the drying means is installed to circulate air to maintain a uniform temperature throughout the entire drying section;

A central control means (900) for controlling the conveying means and the cooling means, controlling the drying temperature and the drying time of the drying subject to be dried, and controlling the power supplied to the drying means;

A conveying means 1100 for conveying the object 10 to be dried to the drying means and conveying the dried object to be dried to the cooling means again;

At least one sheath heater is installed at a predetermined interval, and drying means 1000 for drying the object to be dried by generating heat and far infrared rays when power is supplied;

And a cooling unit 1200 for cooling the object to be dried when the object to be dried that is dried by the drying unit is provided by the conveying unit.

That is, as the conveying means, the conveying means constitutes a conveyor. When the conveying means operates under the control of the central control means, the object to be dried located on the specific conveyor moves through the drying and cooling steps.

The temperature sensing sensor 800 is installed in a drying section in which drying means is installed, detects the temperature and provides the sensed value to the central control means, and the air circulating fan 850 includes a drying section Thereby circulating the air to maintain a uniform temperature throughout the entire drying section.

At this time, if the total drying section is constituted by 30 meters, it can be divided into 3 zones and the drying can be performed at the optimum temperature by utilizing the temperature sensing sensor.

It is also possible to separate the power source so that temperature control for each section is possible.

Further, since the drying means is divided into an upper portion and a lower portion, the production efficiency can be increased and the drying cost can be reduced.

Further, it is possible to ensure a uniform temperature throughout the entire drying line through the air circulation fan.

In other words, the far-infrared ray has a straight line, and it constitutes an air circulation fan to compensate for the disadvantage that it is not suitable for drying a subject having a corner portion.

Through the above-mentioned structure, the quality of the drying apparatus excellent in economical efficiency, environmental friendliness, excellent drying and coating quality is secured, and the drying system suitable for various drying environments of the production factory is constructed, , The drying characteristics of the dried body, and the like, thereby providing an optimum drying system.

FIG. 2 is a conceptual diagram schematically showing the overall configuration of a powder coating and drying system using a far infrared ray sheath heater according to an embodiment of the present invention.

As shown in Fig. 2, the central control means controls the air circulation fan, the drying means, the temperature sensor, the conveying means, and the cooling means.

The control of the conveying means is to provide an operation signal to the operation motor constituted in the conveyor which is the conveying means, so that the conveyor is moved with time.

3 is a block diagram of a central control means of a powder coating and drying system using a far infrared ray sheath heater according to an embodiment of the present invention.

As shown in Fig. 3, the central control means 900 includes:

A power supply controller 910 for controlling the power supply according to the temperature according to the section with reference to the temperature value sensed by the temperature sensor,

An overheat preventing unit 920 for shutting off the power supply when the set threshold value is exceeded,

An air circulation fan operation unit 930 for sending an operation signal to the air circulation fan when a temperature value detected by the temperature detection sensor is exceeded and a preset threshold value is exceeded,

A drying condition obtaining unit 940 for obtaining the set drying condition,

The material information of the allowable temperature, the allowable power density, and the allowable drying speed, which are the drying conditions obtained by the drying condition obtaining unit, and the data setting information of the temperature control, the power control schedule setting, the file name, A drying characteristic database 950 for storing the drying characteristics,

A control condition acquisition unit 960 for acquiring a mode set by the user,

A control mode obtaining unit 970 for obtaining a control mode set by the user when the mode obtained by the control condition obtaining unit is an automatic mode,

A conveying means operation portion 980 for controlling the operation of the conveying means,

And a cooling unit operating unit 990 for controlling the operation of the cooling unit.

Specifically, the power supply control unit 910 controls power supply according to the temperature of each section by referring to the temperature value sensed by the temperature sensor. For example, when the temperature of the first section is set to 300 If the temperature is exceeded, the power supply is cut off.

That is, the power supplied to control the temperature of each section is controlled.

When the threshold value is set to 500, the overheat prevention unit 920 automatically cuts off the power supply when the value exceeds the predetermined value.

The power supply control unit is different from the power supply control unit in that the power supply control unit is for maintaining the set temperature and the overheat prevention unit is for preventing the danger of the drying system failing or exploding.

The air circulation fan operation unit 930 sends an operation signal to the air circulation fan when the temperature value detected by the temperature sensor exceeds a preset threshold value. If the air circulation fan operation unit 930 is set to 250, The air circulation fan is operated to provide uniform drying.

The drying condition obtaining unit 940 obtains the set drying condition. In order to operate the system of the present invention, the user sets the drying condition through the computer terminal installed with the driving program, and acquires the drying condition set by the user .

The drying conditions include material information such as allowable temperature, allowable power density, allowable drying speed, schedule setting such as temperature control and power control, file name including set value and result value for each dry subject to be dried, Data interval, and the like.

At this time, the drying condition obtained by the drying condition obtaining unit is stored and managed in the drying characteristic database.

The control condition obtaining unit 960 obtains a control condition that is displayed on the screen when the user drives the driving program, that is, an automatic mode that automatically performs all operations, and a manual mode that is manually performed .

If the control condition is set to the manual mode, the user performs the drying process by directly controlling the power control and the temperature control, and is executed when there is no preceding drying data related to the drying subject.

Meanwhile, when the mode obtained by the control condition obtaining unit is the automatic mode, the control mode set by the user is obtained through the control mode obtaining unit.

The control mode means a mode set by a user in a power control mode or a temperature control mode.

When the drying time is set for each section by the program, the operation of the conveying means is stopped during the drying time. When the drying time is reached, the conveying means operation portion 980 controls the operation of the conveying means, To operate it.

In addition, the cooling means operation portion 990 is for controlling the operation of the cooling means, and sends an operation signal to the cooling means.

At this time, as shown in FIG. 4,

An object detection sensor 1210 for detecting the entry of the object to be dried,

A detection signal providing unit 1220 for providing the detection signal to the central control unit when the object is detected by the object detection sensor,

And a cooling fan 1230 operated when receiving an operation signal transmitted from the central control unit.

That is, when the object detection sensor 1210 detects the entry of the object to be dried and the entry of the object to be dried is detected by the object detection sensor, the detection signal providing unit 1220 provides the corresponding detection signal to the central control means do.

At this time, an operation signal transmitted from the central control unit is received by the cooling fan 1230 and is operated to perform cooling.

FIG. 5 is a diagram illustrating the construction of drying means of a powder coating drying system using a far infrared ray sheath heater according to an embodiment of the present invention.

As shown in Fig. 5, the drying means 1000 includes:

A sieve heater 100 connected to the power source and generating heat when power is supplied,

An enclosed type explosion-proof terminal box 200 for connecting the electric wire inserted through the electric wire inserting port to the sheath heater and constituting the terminal box cover part on the other side to block the explosion risk by the electric spark,

A hermetic type wire inlet portion 210 for hermetically pulling a wire inserted into the wire insertion port to block an explosion by an electric spark,

A reflector 400 for preventing breakage of the sheath heater and for maximizing heat efficiency by reflecting heat generated from the sheath heater,

And a protection net 410 formed on one side of the reflector to protect the sheath heater.

As described above, the drying means includes the sheath heater 100, the closed type explosion-proof terminal box 200, the closed-type wire inlet portion 210, the reflection plate 400, and the protection net 410.

The reflector is configured to prevent breakage of the sheath heater and to maximize heat efficiency by reflecting heat and far infrared rays generated from the sheath heater. The reflector is disposed at one side of the reflector to protect the sheath heater ) To prevent forced escape from the outside, and is a structure for protecting the sheath heater located inside.

The enclosed type explosion-proof terminal box 200 comprises a hermetically sealed electric wire penetration part 210 at one side to connect the electric wire inserted through the hermetic electric wire entry part to the sheath heater and the terminal box cover part 220 at the other side, The risk of explosion is blocked.

The reflector reflects the far-infrared rays and heat generated from the sheath heater to the open portion of the sheath heater. The reflector may be formed into a curved shape having an inwardly curved cross-sectional shape so as to efficiently reflect far-infrared rays and heat.

6 is a schematic view of a sheath heater of a powder coating drying system using a far infrared ray sheath heater according to an embodiment of the present invention.

As shown in Fig. 6, the sheathed heater 100 includes:

As far-infrared radiation ceramic coated heaters,

A sheath heater unit 110 that generates heat when power is supplied thereto,

A ceramic packing part 120 for sealing a connection part at one end of the sheath heater part,

A coupling part 130 for coupling with the enclosed type explosion-proof terminal box,

An insulator 140 configured to be insulated at one side of the fastening part,

And a terminal unit 150 for connecting to the terminal of the electric wire.

More specifically, when a power source is supplied, a ceramic packing part 120 for sealing a connection part is formed at one end of a sheath heater part for generating heat, and a coupling part 130 for coupling with a closed type explosion- The insulator 140 is formed on one side of the coupling part 130 and the nut part 145 is formed on one side of the insulator part to seal the sealed type explosion- .

In addition, the terminal unit 150 is formed at the end of the sheath heater unit and connected to the terminal of the drawn-in wire to receive power from the electric wire, and the sheath heater unit generates heat and radiates heat and far-

At this time, the enclosed type explosion-proof terminal box includes a bushing 230 formed at one side of the terminal box cover to insulate the enclosed type explosion-proof terminal box.

In the case of the conventional halogen heater, the heater is mounted on the socket so that the terminals of the halogen heater are connected to the connection terminals of the sockets provided at both ends of the reflector, and when power is supplied due to the contact failure, Spark may occur at the connection portion of the heater terminal.

A flammable gas is inevitably generated in the drying process of drying the paint and a spark generated at the connection portion between the connection terminal of the socket and the terminal of the heater acts as an ignition source of the flammable gas generated in the drying process and is exposed to the risk of fire and explosion There is a problem.

However, the sealed type explosion-proof terminal box of the present invention has a sealed type explosion-proof structure unlike the conventional heater and is sealed so as not to be exposed to the outside, whereby the cause of the spark is fundamentally removed, thereby eliminating the risk of fire and explosion .

By providing a powder coating drying system using a far infrared ray sheath heater using electricity through the above-described structure and operation, it is possible to drastically reduce energy cost under an oil price era and low carbon economy system, minimize carbon dioxide generation and reduce environmental pollution, It is possible to minimize the risk of fire and explosion at the industrial site, thereby improving industrial safety.

It will be appreciated by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is to be understood, therefore, that the embodiments described above are to be considered in all respects as illustrative and not restrictive.

The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

800: Temperature sensor
850: Air circulation fan
900: Central control means
1000: drying means
1100: conveying means
1200: Cooling means

Claims (5)

In a powder coating drying system,
A temperature sensing sensor 800 installed in the drying section in which the drying means is installed and sensing the temperature;
An air circulation fan 850 installed in the drying section where the drying means is installed to circulate air to maintain a uniform temperature throughout the entire drying section;
A central control means (900) for controlling the conveying means and the cooling means, controlling the drying temperature and the drying time of the to-be-dried subject to be dried, and controlling the power supplied to the drying means;
A conveying means 1100 for conveying the object 10 to be dried to the drying means and conveying the dried object to be dried to the cooling means again;
At least one sheath heater is installed at a predetermined interval, and drying means 1000 for drying the object to be dried by generating heat and far infrared rays when power is supplied;
And a cooling means (1200) for cooling the object to be dried which is heated when the object to be dried, which is dried by the drying means, is provided by the conveying means, characterized in that the powder coating drying system .
The method according to claim 1,
The central control means (900)
A power supply controller 910 for controlling the power supply according to the temperature according to the section with reference to the temperature value sensed by the temperature sensor,
An overheat preventing unit 920 for shutting off the power supply when the set threshold value is exceeded,
An air circulation fan operation unit 930 for sending an operation signal to the air circulation fan when a temperature value detected by the temperature detection sensor is exceeded and a preset threshold value is exceeded,
A drying condition obtaining unit 940 for obtaining the set drying condition,
The material information of the allowable temperature, the allowable power density, and the allowable drying speed, which are the drying conditions obtained by the drying condition obtaining unit, and the data setting information of the temperature control, the power control schedule setting, the file name, A drying characteristic database 950 for storing the drying characteristics,
A control condition acquisition unit 960 for acquiring a mode set by the user,
A control mode obtaining unit 970 for obtaining a control mode set by the user when the mode obtained by the control condition obtaining unit is an automatic mode,
A conveying means operation portion 980 for controlling the operation of the conveying means,
And a cooling means operation portion (990) for controlling the operation of the cooling means.
The method according to claim 1,
The drying means (1000)
A sieve heater 100 connected to the power source and generating heat when power is supplied,
An enclosed type explosion-proof terminal box 200 for connecting the electric wire inserted through the electric wire inserting port to the sheath heater and constituting the terminal box cover part on the other side to block the explosion risk by the electric spark,
A hermetic type wire inlet portion 210 for hermetically pulling a wire inserted into the wire insertion port to block an explosion by an electric spark,
A reflector 400 for preventing breakage of the sheath heater and for maximizing heat efficiency by reflecting heat generated from the sheath heater,
And a protection net 410 formed on one side of the reflection plate to protect the sheath heater,
The sheath heater (100)
As far-infrared radiation ceramic coated heaters,
A sheath heater unit 110 that generates heat when power is supplied thereto,
A ceramic packing part 120 for sealing a connection part at one end of the sheath heater part,
A coupling part 130 for coupling with the enclosed type explosion-proof terminal box,
An insulator 140 configured to be insulated at one side of the fastening part,
And a terminal unit (150) for connecting the terminal of the electric wire to the terminal of the electric wire. The method according to claim 1,
The cooling means (1200)
An object detection sensor 1210 for detecting the entry of the object to be dried,
A detection signal providing unit 1220 for providing the detection signal to the central control unit when the object is detected by the object detection sensor,
And a cooling fan (1230) operated when receiving an operation signal transmitted from the central control unit.
The method according to claim 1,
The conveying means 1100,
Wherein the powder coating drying system uses a far infrared ray sheath heater.

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