KR200357175Y1 - A drying device of the fluorescence that become application on panel of display by near infrared ray. - Google Patents

Abstract

The present invention relates to a phosphor drying apparatus applied to a panel of a display using near infrared rays, comprising: a drying chamber having an inlet formed at one side and an outlet formed at the other side; An object transfer device for loading an object such as a panel of a display coated with graphite and fluorescent material through an inlet of the drying chamber and unloading through an outlet; A near infrared heater module installed inside the drying chamber and irradiating near infrared rays to the object with a near infrared lamp; And a control unit for sensing a drying progress state of the object by a temperature sensing unit and applying a control signal to the near-infrared heater module, so that the drying unit can be completely dried within a very short time. It is possible to shorten the heater preparation time, reduce the energy consumption time by eliminating energy consumption during unnecessary time, and because it is a drying method by near infrared rays, it improves the quality such as adhesion of the coating and also harmful gas in the heater. Does not occur has an environmentally friendly effect.

Description

A drying device of the fluorescence that become application on panel of display by near infrared ray.}

The present invention relates to a phosphor drying apparatus applied to a panel of a display using near infrared rays, and more particularly, it is possible to cool the heater and to determine the degree of drying by sensing the temperature of an object, and to use the panel of the display using environmentally friendly near infrared rays. It relates to a phosphor drying apparatus applied to.

In general, a part of the vacuum container as a part of the front surface of the CRT, that is, a screen, is a fluorescent surface formed inside the panel where image information transmitted and received as an electric signal is converted into final visual information, which is a three primary color of light. Three-color phosphor pixels consisting of R (Red), G (Green), and B (Blue) are now in the process of drying the phosphor coated on the panel as a component of the image surface for deposition on the inner surface of the panel. The prior art is drying by convection drying method using a hot air drying furnace or IR (InfraRed, infrared) heater + hot air, and even if the heater module uses a far infrared heater module or near infrared, its energy density is low and its Because the flatness of energy is uneven and it dries far away from the product, drying takes a long time. It is composed of a drying furnace of the slo- er stage or a long drying furnace of 10M or more, and a large amount of products are passed through the conveying device for drying. Another reason is that when drying by heat conduction, the surface of the coating layer is formed by heat conduction. Since it hardens first, heat penetrates into the inside, so much time is required to take out H2O and OH- from the object to be dried. Because there is no choice but to.

In addition, in the conventional drying method, the object is transferred while facing the heater unit and the object vertically in the vertical state, not up and down, while using the heat conduction method. It is difficult to expect energy transfer efficiency of 100%.

In addition, the conventional drying method takes a lot of preparation time to maintain the temperature in the drying furnace to a certain temperature at the first start-up, and even if the object is not put in while maintaining a constant temperature, electricity and fuel must always be consumed. have. If the transfer means of the product is stopped due to a failure while maintaining at a constant temperature there is also a problem that can cause a problem in many products that were being transferred.

In order to maintain the mass production environment of the drying furnace, the drying furnace and its surroundings must be thermally treated to maintain an additional facility.

An object of the present invention for solving the above problems, when the object is dried using a near-infrared while transporting the object using a display coated with a functional material, that is, a conventional production line for transporting the object to be dried 3,000 ~ By using the output of more than 3,500K and increasing the share of near-infrared ray with the wavelength range of 0.76 ~ 1.4mm, and using the physical property of high thermal density with the energy density of 800 (KW / ㎡), the strong radiant energy penetrates inside the coating layer of the object to be dried. The present invention provides a phosphor drying apparatus applied to a panel of a display using near-infrared light, which allows complete drying in a very short time (5 to 10 seconds) because it instantly evaporates H 2 O and OH-.

In addition, another object of the present invention is a short wavelength near-infrared irradiation method of 0.76 ~ 1.4㎛ high openness of the drying room, the design of equipment in the installation environment is free, and the heater preparation time is short because the heater is operated only by electric energy, It is to provide a drying device including a near-infrared heater module that can be operated only when the input is reduced to reduce the electricity consumption time.

In addition, another object of the present invention is to provide a near-infrared heater module having an explosion-proof function by preventing harmful gas from being generated in the heater because it is a near-infrared irradiation type, and preventing harmful gases from being generated from being dried.

In addition, another object of the present invention is near-infrared irradiation type, so even if the air is injected between the heater module and the object by an external air spraying device installed in front of the near-infrared heater module, it accelerates the drying of the object and prevents the drying of the object. The present invention provides a near-infrared heater module having a function of smoothly discharging various generated evaporative gases and harmful gases.

In addition, another object of the present invention is to dry the functional material coated on the product by sensing the temperature of the product being dried, so that the drying to the optimal drying quality according to the characteristics of the functional material using near infrared rays Provided are a phosphor drying apparatus applied to a panel of a display.

In addition, another object of the present invention is a near-infrared irradiation type, so in the configuration of the near-infrared heater module and the object, the same energy is transmitted in all the configurations in the up, down, left, and right directions. The phosphor drying apparatus applied to the) is provided.

1 is a schematic view showing a phosphor drying apparatus applied to a panel of a display using near infrared rays according to an embodiment of the present invention

2 is a schematic view showing a near infrared heater module of a phosphor drying apparatus applied to a panel of a display using near infrared rays

3 is a schematic view showing a cross section of a near infrared heater module of a phosphor drying apparatus applied to a panel of a display using near infrared rays;

4 is a block diagram illustrating a control unit of a phosphor drying apparatus applied to a panel of a display using near infrared rays.

5 is a control flow chart of a phosphor drying apparatus applied to a panel of a display using near infrared rays

6 is a conventional drying apparatus according to the time of the apparatus according to the present invention

Graph showing drying rate

A phosphor drying apparatus applied to a panel of a display using a near infrared ray of the present invention for achieving the above object is a drying chamber in which the inlet is formed on one side and the outlet is formed on the other side; An object transfer device for loading an object through an inlet of the drying chamber and unloading through an outlet; A near infrared heater module installed inside the drying chamber and radiating near infrared rays to an object that is a display coated with a functional material; And a control unit for sensing a dry state of the object with a non-contact temperature sensing unit and applying a control signal to the near-infrared heater module.

In addition, the near-infrared heater module, the near-infrared lamp is connected to the power driver connected to the control unit for generating a near infrared ray; A housing having a near-infrared lamp holder formed therein so that the near-infrared lamp can be attached and detached, and a glass plate assembled on one side to surround the near-infrared lamp; A reflection plate installed on an inner surface of the housing to reflect the near infrared rays irradiated from the near infrared lamps so as to be concentrated in the direction of an object without receiving interference between the near infrared lamps and having a cooling function; And an air chamber installed in the housing to cool the heat generated by the near infrared lamp itself and at the same time, the air stays inside the housing to maintain a pressure difference with the outside, and to be discharged through a discharge port formed in the housing to discharge external harmful gases. Internal air injection device to prevent the inflow; And is installed in front of the near infrared heater module to accelerate the drying of the object and to inject air between the near infrared heater module and the object to discharge the harmful gas smoothly, the functional material coated on the object The drying may be made by including an external air injector that serves to blow the various evaporative gases or harmful gases generated while drying does not affect the drying operation.

In addition, it is preferable to detect the internal temperature of the heater module for applying the internal temperature signal of the heater module to the control unit to prevent the overheating of the heater module by measuring the temperature inside the housing with the housing internal temperature sensing means of the near-infrared heater module of the present invention And non-contact object temperature sensing means installed in the near-infrared heater module and measuring an object temperature during drying to apply an object temperature signal to the controller to achieve optimal drying; The elevating device of the near-infrared heater module for raising and lowering the height of the near-infrared heater module is adjusted according to the type or size of the object.

On the other hand, the control of the present invention for achieving the above object is composed of a near-infrared heater module for irradiating near-infrared to the object and a non-contact temperature sensing means, according to the type or form of the functional material coated on the object of the near-infrared heater It may be made to include a control device of the phosphor drying apparatus applied to the panel of the display using the near-infrared to dry by setting the irradiation amount or irradiation time and the temperature of the object to be dried.

Hereinafter, a phosphor drying apparatus applied to a panel of a display using a near infrared heater module and a near infrared ray having the same and a control method thereof according to exemplary embodiments of the present invention will be described in detail.

First, as shown in FIG. 1, the phosphor drying apparatus applied to a panel of a display using a near infrared ray according to an exemplary embodiment of the present invention includes a drying chamber 7, an object transfer device, a near infrared heater module, And a control unit 9.

That is, the drying chamber 7 is a place where an inlet is formed on one side and an outlet is formed on the other side, where the ventilator 22 discharges gas and heat inside the drying chamber 7 to the outside as shown in the drawing. Can be installed.

Since the drying chamber 7 is made of a radiation of near-infrared rays rather than heat transfer using hot air in a drying process, unlike the conventional semi-sealed or completely sealed hot air drying method, the drying air does not need to be trapped. A separate opening and closing device is not necessary at the inlet or the outlet of the drying chamber 7, and the open type drying chamber 7 can also reduce the capacity of the ventilator 22 because the ventilation is smooth.

In addition, the object transfer device of the present invention is to load the object through the inlet of the drying chamber (7), and unloading through the outlet, various types of loading and unloading device can be used, but the existing product production line It is possible to use the same transfer apparatus 8 as.

In addition, the transfer device (8) is installed through the drying chamber (7), the object that can detect the input and output of the object (D) at the irradiation start point and the irradiation end point of the near-infrared heater module (1), respectively The sensing means is installed.

Here, the object detecting means may be a very different type of object detecting sensor 81 (contact or non-contact optical sensor, etc.) for monitoring the proximity of the object.

Accordingly, the object detection sensor 81 is connected to the control unit 9 to be described later, and the control unit 9 receives a position signal of the object D from the object detection sensor 81 to receive a near infrared heater module. It is possible to determine whether or not to operate (1), and whether or not the transfer device (8).

On the other hand, the near-infrared heater module 1 of the present invention is installed in the drying chamber (7), the near-infrared lamp 12 of FIG. The near-infrared lamp 12 can be modularized into a separate object and be applied and installed in various places or locations.

The near-infrared heater module 1 may be any type and type of heater capable of emitting near-infrared rays, but preferably, as shown in FIGS. 2 and 3, the near-infrared lamp 12 and the housing ( 18 and the near-infrared heater module 1 including the reflector 13 may be used.

That is, the near-infrared lamp 12 is a plurality of near-infrared lamps 12 that generate the near-infrared light by connecting the power driver of FIG. 4 connected to the control unit 9 to each of the near-infrared lamps 12. The number and individual outputs of the lamps 12 which are individually controlled by () and operated according to the characteristics of the object (D) or the dry state can be adjusted.

In particular, the near-infrared lamp 12 has a wavelength in the range of 0.76 to 1.4 μm and has a very high permeability, so that the near-infrared ray has a high radiation energy density physical property capable of completely penetrating to the bottom of the coating layer of the functional material and completely drying the object within a few seconds. Can be investigated. Since such near infrared rays are usually radiated when the heat source is heated to a high temperature of 3,000 to 3,500 K or more, a heat source having durability such as a tungsten coil is used.

2 and 3, the housing 18 of the near-infrared heater module 1 is a pair of cover plates-1 (30) and a pair of cover flakes-2 (31) facing each of the square pillars 32 4) is formed in a rectangular frame shape connected to four places, and a reflecting plate 13 is formed therein, and a plurality of lamp holders 11 are formed inside the reflecting plate 13 so that the near-infrared lamp 12 can be attached and detached. The glass plate 20, which is disassembled on one side of the housing 18, is assembled to surround the near-infrared lamp 12.

Accordingly, the glass plate 20 is separated from the housing 18, and the near-infrared lamp 12 fastened by the lamp holder 11 configured in the reflector plate 13 inside the housing 18 is easily disassembled and replaced. Or you can clean it.

In addition, the reflecting plate 13 is installed in the housing 18 so that near-infrared rays irradiated from the near-infrared lamp 12 are concentrated on one side such that the near-infrared rays are concentrated in the irradiation direction of the object through the glass plate 20. The reflective surface to reflect is formed.

On the other hand, when the near-infrared heater module 1 of the present invention is operated, the reflecting plate 13 and the housing 18 close to the near-infrared lamp 12 by the heat generated from the near-infrared lamp 12 to prevent overheating (13) and the cover plate of the housing 18, and the flow path 19 which can flow the coolant which flows into the inside of the square pillar is comprised.

Here, the coolant rises to a temperature that is cooled by passing through the reflector plate 13 and the housing 18 of the near-infrared heater module 1, and is recovered to the coolant supply device 50, but when it enters the near-infrared drying module 1 again, It is cooled down to the set low temperature.

Preferably, the flow paths and channels of the cover plates 1 and 2 constituted by the housing 18 are characterized by the extrusion method in the shape of FIG. 2 without cutting.

In particular, the internal air injector 40 is added to the air flow passage 17 through which air is supplied from the outside in addition to the flow path of the cover plate-1 30 composed of the housing, and only one of the two cover plates-1 30 is provided. A plurality of nozzles 34 corresponding to the position of the near infrared lamp 12 are processed and configured.

And the air supplied from the outside is the air flow 35 through the passage 17 and the nozzle 34 of the cover plate-1 (30) as shown in Figure 3 to cool the near-infrared lamp 12 first and to overheat inside the housing After the prevention function, the inside of the housing 18 is higher than the outside air pressure to exit through the outlet 21, which prevents the harmful gases, such as the outside to prevent pollution and explosion-proof functions.

Meanwhile, the near-infrared heater module 1 of the present invention may further include a housing internal temperature sensor 22, a non-contact object temperature sensor 2, and a near-infrared heater module elevating device as necessary.

That is, the non-contact object temperature sensor 2, which is a kind of temperature sensing means, is installed at the rear of the near-infrared heater module 1 to detect a variety of types of non-contact temperature for detecting thermal energy generated from the object D at the end of drying. A sensor can be used, and the technology for such a non-contact temperature sensing means is already commercialized and widely spread, which can be modified and changed without departing from the technical spirit of the present invention.

Accordingly, the control unit 9 receives a temperature signal of the end of drying of the object D from the non-contact object temperature sensor 2, and compares the object with a complete drying temperature reference value so that the object is completely dried. Adjust the output.

In addition, since the inside of the housing is overheated and the signal is applied from the inside temperature sensor 22 because the control unit 9 receives a signal only at a predetermined temperature or more, the inside temperature sensor 22 of the control unit 9 receives the signal. ) Can prevent excessive overheating by cutting off the power supplied to the near-infrared lamp.

In addition, the elevating device of the near-infrared heater module (1) is to elevate the near-infrared heater module (1) according to the size of the object (D), a very various types of elevating device such as a hydraulic cylinder or a pneumatic cylinder can be used. However, preferably, as shown in FIG. 1, a lifter 5 operated by a motor 6 and a rotating screw rod is applied. Can be.

Therefore, the user can adjust the installation height of the near-infrared heater module 1 according to the height of the object D using the lifter 5, and in addition, the motor 6 is connected to the control unit 9 so that the height can be adjusted. It is possible to automatically adjust the installation height of the near-infrared heater module 1 according to various kinds of objects.

On the other hand, the external air injector 3 is installed in front of the near-infrared heater module to accelerate the drying of the object and smoothly discharge the harmful gas into the air flow 36 as shown in FIG. 3 between the near-infrared heater module and the object. By spraying air, it serves to blow the various evaporative gases or harmful gases generated while the functional material coated on the object is dried does not affect the drying operation.

Here, the external air injector 3 may be applied to a wide variety of air injectors including an air ejection nozzle, an air ejection tube, a valve, a compression pump, and the like, but preferably to induce forced flow of air. Air knife can be applied.

The evaporative gas or harmful gas is discharged to the outside of the drying chamber by the ventilator 22 of the drying chamber.

Comparing the conventional method and the conventional method using the near-infrared heater module 1 of the present invention, the near-infrared heater module of the present invention, as shown in Figure 6, using the near infrared energy from the bottom surface of the object coating layer to the upper surface The drying process proceeds quickly within a few seconds, and since the upper surface is finally dried, the time taken for the drying curve of the present invention to reach 100% drying rate in a proportional curve with time is much higher than that of the conventional method. short.

However, in the conventional method, when drying by a hot air drying furnace or a convection drying method using an IR (InfraRed, infrared) heater + hotair, the surface of the coating layer is first hardened by heat conduction, and then heat is penetrated into the interior. Good drying requires a lot of time because it can only be dried slowly, and even if the heater module uses a far-infrared heater module or near-infrared radiation, evenly distributed energy is uneven and its density is low. It is difficult to deliver near-infrared rays sufficiently to dry objects because they are dried at a distance from the objects to be dried, so the time (t2) to reach 100% complete drying is very long or even only the upper surface is dried, Sometimes it is impossible to completely dry noodles, such as cotton Can.

On the other hand, as shown in Figure 4, the control unit 9 according to an embodiment of the present invention is a power switch, emergency switch, near-infrared heater module lifting switch, object input and output detection means, object temperature sensing means, near infrared heater As described above, a module internal temperature sensing means, a speed sensing means of a conveying device, and the like, as described above, sense the drying state of the object from the sensing means consisting of various sensors and switches, and then the individual power driver of the near infrared lamp or the external air. Controls the injector 3, the solenoid valve driver for opening and closing the solenoid valve connected to the internal air injector 40 and the coolant line, and displays information such as product temperature and operating time detected from various means. can do.

In particular, while detecting the temperature at which the object is dried from the non-contact object temperature sensing means (2) installed at the exit of the near infrared heater module (1) to dry only to a temperature set to a random value to prevent damage to the object by overheating at the same time Depending on the type of functional material to be coated on, drying at the optimum temperature is possible, so it is possible to dry with the best quality.

The function of the control unit 9 of the phosphor drying apparatus applied to the panel of the display using the near-infrared of the present invention described above will be described in more detail, which is applied to the panel of the display using the near-infrared of the present invention. As shown in FIG. 4, the control of the phosphor drying apparatus includes a preparation step S1 of preparing an initial installation, a drying step S2 of drying the object D in the drying chamber, and loading / unloading the object. The completion step (S3) will be repeated.

That is, the preparation step (S1), the height of the near-infrared heater module according to the reference value setting step for setting the reference value of the control unit, such as the irradiation amount of the near-infrared lamp 12, the irradiation time, the speed of the transfer device, and the type or shape of the object. The heater module is made up and down adjusting step of adjusting. In addition, various reference values, programs, and setting values may be input to the controller as positions.

Subsequently, the drying step (S2), the object input detection step (S21) for detecting the input of the object by the object detection sensor of the object transfer device, and near-infrared to irradiate the near-infrared to the object detected the input to dry Near-infrared heater module operation step (S22) that the heater module is operated, and the object output detection step (S23) for detecting the output of the object is irradiated by the object detection sensor of the object transfer device.

Here, the near-infrared heater module operation step 22, the object temperature sensing step 221 for detecting the temperature of the object in a non-contact manner, and the heater module internal temperature sensing step for detecting the temperature inside the near-infrared heater module for irradiating the object ( 222 and adjusting the number of movable near-infrared lamps to apply a control signal to the power driver of the near-infrared lamp to operate only the necessary near-infrared lamp among the plurality of near-infrared lamps mounted inside the heater module according to the size of the object to be loaded (S223). And the near-infrared lamp power adjusting step 224 of controlling the amount of power applied to the near-infrared heater lamp 12 by determining the degree of drying of the object based on the sensed temperature of the object.

Subsequently, the completion step (S3) is a step of unloading the object to be completed from the drying chamber to the outside by the control unit that detects the drying progress state of the object by the non-contact temperature sensor to control the object transfer device (S31) ), And loading the undried new object into the drying chamber (S32), and after this completion step (S3), the drying step is repeated and a large number of objects can be completely dried in rapid succession. .

The present invention is not limited to the above-described embodiment, of course, can be modified by those skilled in the art without departing from the spirit of the present invention.

For example, in the embodiment of the present invention, the light beam irradiated to the object is limited to near infrared rays, but all kinds of light beams capable of transferring heat energy may be applied, and the object may also be any kind of object or animal or plant that needs to be dried.

Therefore, the scope of the claims in the present invention will not be defined within the scope of the detailed description, but will be limited by the claims and the technical spirit thereof.

As described above, the near-infrared heater module of the present invention and the display drying apparatus having the same constitute a part of the vacuum container as a part corresponding to the front surface of the CRT, and at the same time, the image information transmitted and received as an electric signal is the final visual information. The fluorescent surface formed inside the panel to be converted into three primary colors of the three primary colors of light, R (Red), G (Green), and B (Blue), is used as a component of the image plane. For the purpose of drying, it is possible to completely dry the coating layer in a very short time by irradiating strong radiant energy with near-infrared heater, and because it is a method of irradiating near-infrared light of short wavelength with high energy density, it is possible The heater preparation time is short because the heater is operated by electric energy and because it is near infrared irradiation type It is environmentally friendly because no harmful gas is generated in the site, and it is characterized by having an explosion-proof function by preventing harmful gas generated from the object from flowing into the near-infrared heater module.

In addition, the control method of the present invention has a function of operating the near-infrared heater module for a continuous or predetermined time by setting to a certain amount of power and the temperature at which the object is dried from the non-contact object temperature sensing means installed in the outlet of the near-infrared heater module (1) It detects and dries only to a certain temperature to prevent damage of the object caused by overheating and at the same time it can be dried at the optimum temperature according to the kind of functional material coated on the object. It is characterized by having a function to.

Claims (9)

A drying chamber in which an inlet is formed at one side and an outlet is formed at the other side; A part of the vacuum container is formed through the entrance of the drying chamber, that is, the front surface of the CRT, that is, the screen, and is formed inside the panel in which the image information transmitted and received as an electric signal is converted into final visual information. Loading a panel on which an image plane of a three primary color phosphor pixel composed of R (Red), G (Green), and B (Blue), three primary colors of light, is deposited, and unloading through an exit. Object transfer device to be; A near infrared heater module installed inside the drying chamber and irradiating near infrared rays to the object with a near infrared lamp generating near infrared rays; A control unit for sensing a drying progress state of the object by a temperature sensing unit and applying a control signal to the near infrared heater module; Phosphor drying device applied to a panel of the display using a near infrared ray, characterized in that comprises a. The method of claim 1, The drying chamber is a phosphor drying apparatus applied to the panel of the display using a near infrared, characterized in that the ventilator is installed to discharge the heat inside the drying chamber to the outside. The method of claim 1, The object transfer device is a transfer device installed through the drying chamber, the object detection means for applying the position signal of the object to the control unit at the irradiation start point and the irradiation end point of the near infrared heater module is installed. A phosphor drying apparatus applied to a panel of a display using near infrared rays. The method of claim 1, The near infrared heater module, A plurality of near-infrared lamps connected to the control unit to generate near-infrared rays, respectively; A plurality of near-infrared lamp holders are formed therein so that the near-infrared lamps can be attached and detached, and a glass plate is assembled on one side to surround the near-infrared lamps, and one side has a passage configured to allow external air to be blown out. A housing for cooling the NIR lamp first and then forming an air chamber in which the air stays so as to have a pressure difference with the outside so that no harmful gases are introduced; A reflection plate installed in the housing and reflecting the near infrared rays irradiated from the near infrared lamp to be concentrated in one direction; A phosphor drying apparatus applied to a panel of a display using near infrared rays, characterized in that comprises a. The method of claim 4, wherein An object temperature sensing means installed at the rear of the near infrared heater module and applying an object temperature signal to the control unit so as to detect the temperature of the object in a non-contact manner during drying and achieve optimal drying; A phosphor drying apparatus applied to a panel of a display using near infrared rays. The method of claim 4, wherein It is installed in front of the near-infrared heater module and accelerates the drying of the object without hindering the drying of the object even when injecting air between the near-infrared heater module and the object, and smoothly discharges various evaporative gases or harmful gases generated during drying. A phosphor drying apparatus applied to a panel of a display using near infrared rays, characterized in that it further comprises an external air injector. The method of claim 4, wherein Near-infrared heater module lifting device for raising and lowering the height of the near-infrared heater module is adjusted according to the size or position of the object; phosphor drying device applied to the panel of the display using a near-infrared, characterized in that further comprises . delete delete