KR810001690Y1 - Hot wind generator for dryer - Google Patents

Abstract

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Description

Hot Air Generator of Hot Air Direct Drying Equipment

1 is a longitudinal longitudinal cross-sectional view of the device,

2 is a simplified representation of the installation usage status,

3 is a cross-sectional view in the width direction of the present invention seen from the line A-A of FIG.

4 is a longitudinal longitudinal cross-sectional view of a conventional hot air generator.

The present invention relates to a hot air generator of the hot air drying machine that can be adjusted to the temperature smoothly.

Metal printing that bakes the coating film on the adherend requires the accurate temperature maintenance in the drying house as the economical cheap paint is used.

In other words, when expensive quality paint is used, the effect of temperature change in the drying house on the hardening of the coating film is small.However, when using a low-cost paint, the coating film is peeled off from the metal surface if the temperature is not maintained in the drying chamber. When baking is completed in a state where a constant temperature is maintained, it is possible to obtain a coating film having good properties such as adhesion gloss and hardness comparable to that of using an expensive, high-quality paint.

However, the hot air generator of the conventional “hot air direct drying device” is thickly designed with a refractory brick so that the heat pipe installed therein can continuously receive high heat, and according to the temperature change in the drying house due to the heat of the heat pipe. It is not possible to supply hot air at an appropriate temperature.

Therefore, in order to lower the temperature in the drying house, it is not possible to temporarily lower the temperature by introducing cold air from the outside or perform a temperature control function completely by such an operation. In addition, in the conventional hot air generator, the hot air recovered from the drying house is not properly connected with the heat receiving tube, and hot air generation is also inefficient.

The present invention relates to a hot air generator that improves such a problem.

In other words, instead of the heat pipes of the refractory bricks, heat pipes sensitive to temperature changes were used.

Also, the air recovered from the drying house is reflected and guided evenly to the crater of the heat receiving tube so that the steel tube can withstand continuous high heat, and the recovered air cools the heat receiving tube by allowing the recovered air to pass through the heat pipe. The gas flow rate in the tube was accelerated so that the hydrothermal tube was not heated too much.

In addition, the air thus recovered is sufficiently connected with the flame in the heat receiving tube to obtain hot air with stable temperature. As a result, in the present invention, it is possible to sensitively supply stable hot air at an appropriate temperature at all times without introducing cold air from the outside.

Referring to the present invention in detail according to the accompanying drawings as follows. The conventional hot air generator is equipped with a refractory wall heat-receiving pipe 61 in which a crater is connected to a burner 1 in a hollow container 5 insulated with heat insulating material 8, as shown in FIG. A blower (3) is provided at the end and the air return pipe (4) is connected to the circumferential wall of the canister (5). The hot air is blower (3) and hot air discharge pipe (at the end of the canister (5) as described in FIG. The air guided into the drying bin 11 and recovered from the drying bin 11 through 12 is introduced into the barrel 5 again through the air return pipe 4 and the main wall of the barrel 5.

However, the present invention is equipped with a hydrothermal steel pipe (6) with a spaced apart burner (1) in the barrel (5).

The heat-retaining steel pipe 6 is positioned in the center of the cylinder 5 as in the conventional heat-receiving tube 61, and fixes the air shielding reflector 7 extending from one wall of the air recovery tube 4 into the cylinder 5. Guide the air towards the crater 6 '.

The recovery pipe 4 may be divided into several widths and divided into a plurality of guide plates 71, 72, 73, and 74.

In this case, the tip positions of the guide plates 71, 72, 73, 74 are formed by receiving the air flowing in the recovery pipe partitioned by the guide plates 71, 72, 73, 74, as shown. 6) Be in touch with the surroundings and be careful to guide quietly toward the crater (6 ').

To this end, in the implementation of the present invention in the installation of the guide plate, the upper part of the chafe reflector plate 7 and the guide plates 71, 72, 73, 74 are visible (7 ') (71') in the crater 6 'side The size of (72 ') (73') 74 'partitioned the recovery tube 4 into guide plates 71, 72, 73 and 74, so as to be proportional to the amount of air flowing in the partitioned recovery tube, respectively.

Reference numeral 9 denotes a discharge tube of the blower, 10 denotes a flame, and arrows indicate a direction in which gas flows.

The effect is as follows.

In the conventional hot air generator, when the blower 3 at the end of the cylinder 5 is operated, the air is sucked into the cylinder 5 via the air recovery pipe 4 connected to the drying house 11, and the hydrothermal sections 61 are used. Is heated again in the drying house 11 via the exhaust pipe 12 connected to the blower outlet 9, so when fired at the burner 1 connected to the crater of the heat receiving tube 61, the firebrick In the heat receiving tube 61, the flame 10 is filled so that the refractory brick heat receiving tube 61 is heated, and the air passing through the barrel 5 is connected to a part of the wall of the refractory brick heat receiving tube 61. The hot air is generated by mixing the flame passing through the refractory brick heat exchanger tube 61 at the end of the barrel 5.

The hot air generated in this way is evenly supplied to the drying house 11 at a constant pressure by the blower 3, and the tub (through the collecting pipe 4 in the drying house 11 by the suction force of the same blower 3). 5) and reheated as described above.

Such a conventional drying apparatus uses a refractory brick heat-receiving tube 61, so that the temperature rise time is slow, and once the heat is reddish with sufficient heat, the temperature of the burner is reduced quickly by reducing the burner flame. Can't.

Therefore, in order to lower the temperature of the hot air, it is necessary to drill a hole in the wall of the barrel 5 and introduce cold air from the outside into the cylinder to cool the heat receiving tube 61, thereby causing a large amount of heat loss. The introduction makes the temperature distribution in the drying house unstable.

However, in the present invention, the air entering the barrel 5 from the drying house 11 by the suction force of the blower 3 is directed toward the crater 6 'along the outer wall of the hydrothermal steel pipe 6 heated by the reflector 7. It is heated while being guided, and then joins with flame (10) in the crater (6 ') of the hydrothermal steel tube (6) and heats the mixture sufficiently with the flame while passing through the hydrothermal steel tube (6) to obtain a stable hot air and change the temperature It is to use a hydrothermal steel tube 6 which is sensitive to heat and has a small amount of heat, so that the water heat tube is immediately cooled by the air recovered from the drying house 11 by reducing the flame without introducing cold air from the outside. It may also lower the temperature.

That is, if the flame 10 is reduced, the amount of heat supplied decreases, while the air recovered from the drying house 11 into the barrel 5 contacts the outer wall of the steel pipe 6 to cool the steel pipe 6 toward the fireball 6 '. This is because the heat of retention of the steel pipe 6 also decreases rapidly because it is moved.

In addition, the air recovered in the barrel 5 lowers the temperature of the outer wall of the hydrothermal steel pipe 6 as described above, and the recovered air contacts the flame 10 at the crater 6 'of the hydrothermal steel pipe 6 again. As it passes through the hydrothermal steel pipe, the gas flow rate in the hydrothermal steel pipe 6 is increased, and the contact density between the flame and the steel pipe 6 decreases, so that the heat load of the hydrothermal steel pipe 6 is reduced.

In addition, the air return pipe 4 is divided into several guide plates, and the areas 7 ', 71', 72 ', 73' and 74 'visible from the crater side of the guide plate guide the recovery pipe 4. Since the air flows through the recovery pipe 4 to the crater 6 'of the hydrothermal steel pipe 6 through the recovery pipe 4, even though the gas traveling direction changes, It is distributed at the same flow velocity and density on the outer wall of the hydrothermal steel pipe (6) and guides the flame (10) correctly to the center of the hydrothermal steel pipe (6) to increase the effect of cooling or reducing the heat load of the hydrothermal steel pipe (6). .

As described above, the present invention does not introduce external cold air, so the heat loss is low, the heat load of the hydrothermal steel pipe is reduced, so that the hydrothermal steel pipe can be used for a long time, the temperature in the drying house can be stably maintained accurately, and the refractory brick tidal heat is generated. Unlike pipes, it supplies clean hot air, which contributes to the improvement of quality of baked goods.

Claims (1)

As shown in the figure, a heat pipe is installed in the canister 5, which is insulated with a heat insulator and equipped with a burner 1, a blower 3 is installed at the end of the canister 5, and an air recovery tube is provided at the wall of the canister 5. In the well-known thing which connected (4), the air shield reflection board which extended one wall of the air return pipe 4 in the cylinder 5 equipped with the water-heated steel pipe 6 at intervals with the burner 1 is provided. Hot air generator of the direct-drying device, characterized in that guide the air toward the crater (6 ') by fixing the).