KR20020024693A - Drying apparatus - Google Patents

Abstract

PURPOSE: A dryer is provided to reduce an energy consumption required to a dryer by preheating an absorbing air using a solar radiation heat and by recovering a heat from a discharging air after drying. CONSTITUTION: A dryer comprises a drying chamber(11) for drying an article to be dried. A solar heat radiate plate(20) is installed to an outside upper surface of the dryer and heats an air absorbed in primarily by a solar heat. An air suction inlet(21) for absorbing the air is formed at one side of the solar heat radiate plate(20). A panel(27) having a plurality of a punched air suction inlet(21) is installed at a rear side of the dryer(10) to form uniformly a flow rate distribution. One end portion of a duct(30) is connected at a lower surface of the solar heat radiate plate(20) and the other end is connected with the panel(27), thereby guiding the air to the chamber(10). A burner(30) is installed at an inner side of the duct(30) and heats the primary heated air. A discharging duct(50) is installed at a front surface of the drying chamber, and discharges the air of an inside into an outside of the dryer.

Description

Drying apparatus {Drying apparatus}

The present invention relates to a dryer, and more particularly, by installing a solar panel and allowing the air sucked through it to be heated by solar radiation, high efficiency can be obtained and circulated according to ambient temperature and humidity conditions. The present invention relates to a dryer which can obtain an optimum drying efficiency by allowing the air amount to be adjusted.

In general, methods for drying agricultural products are roughly classified into natural drying by daylight and forced drying by a mechanical drying device.

In recent years, the forced drying generally carried out has a somewhat different configuration, but convection hot air in a drying furnace equipped with a heating means to obtain evaporated moisture by the hot air, thereby obtaining a dried product. The device is in use.

3 is a schematic cross-sectional view of a conventional dryer. As can be seen in this figure, the conventional dryer 70 includes a boiler 71 that generates heat by burning fuel through a burner (not shown), a heat exchanger 73 installed at the top of the boiler, and a dried product. The structure of the drying chamber 75 which dries this, and the fan 77 which forms the flow of air are employ | adopted.

In such a dryer, the air sucked into the boiler absorbs the heat of combustion and flows out to the heat exchanger in a high temperature state. External low temperature air flows into the heat exchanger by the fan, and heat exchanges with the high temperature air in the heat exchanger to increase the temperature, thereby lowering the relative humidity and entering the drying chamber.

Inflow air with low relative humidity absorbs moisture from the dry matter in the drying chamber and is discharged to the outside.

However, in the conventional dryer as described above, since the heat exchange between the air heated in the boiler and the air introduced from the outside is not sufficient, the heated air is discharged through the communication at a high temperature, so that a considerable amount of thermal energy is lost and the high temperature even at the exit of the drying chamber. In addition, the high energy air of high humidity is released to the outside, there is a disadvantage that the energy loss is inevitable.

Therefore, an object of the present invention, unlike the existing hot air dryers that depended only on the heat of combustion by configuring a drying system equipped with a solar radiation plate, preheat the air sucked in using solar radiation heat and dry it through heat recovery from the air discharged after drying. It is to provide a dryer that can control the drying environment according to the condition of the building by reducing the energy consumption required by the installation and installing air ducts and dampers.

1 is a cross-sectional view showing the internal configuration of the dryer according to the present invention,

Figure 2 is a side cross-sectional view of the solar radiation plate according to the present invention,

3 is a schematic cross-sectional view of a conventional dryer.

Explanation of symbols on the main parts of the drawings

10: dryer 11: drying chamber

20: solar radiation plate 21: air intake

23: suction hole 25: air inlet

27 panel 29: array recovery surface

30: duct 31: burner

33: fan 40: suction damper

50: discharge duct 53: discharge damper

55: discharge port 57: bypass damper

According to the present invention, in the dryer having a burner and a drying chamber to generate hot air to dry the dry matter, the dryer is positioned along the longitudinal direction on the outer upper surface of the dryer and sucked with an air intake at one side. A solar radiation plate formed so as to heat air primarily by solar radiation heat; A panel installed on the rear wall of the dryer and having a plurality of suction holes to uniform the flow rate distribution of the air introduced therein; A duct connected from a lower surface of the solar radiation plate and connected to a panel side installed at the rear of the dryer and guiding the first heated air by the solar radiation plate to the drying chamber side; And a discharge duct installed in front of the drying chamber and discharging air in the drying chamber to the outside of the dryer.

Here, the solar radiation plate is formed in the shape of the end of the wave shape is formed on the surface of the solar radiation plate is effective to further include a plurality of suction holes for sucking the solar radiation heat.

The duct may include a suction damper that sucks the solar radiation generated by the solar radiation plate; A fan for guiding suction to the drying chamber through the suction damper; It is preferable to further include a burner for drying the air sucked by the fan at a higher temperature.

In addition, the discharge duct further comprises an intermediate damper and a discharge damper for guiding the discharge of the air in the drying chamber, the discharge duct is effective to have a discharge port at one end.

On the other hand, the dryer preferably further comprises a bypass damper for connecting the upper side of the front region of the drying chamber and the duct.

In addition, it is effective to be inclined at a predetermined angle toward the other side starting from one side in the longitudinal direction of the dryer.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the present invention. 1 is a cross-sectional view showing an internal configuration of a dryer according to the present invention, Figure 2 is a side cross-sectional view of the solar radiation plate according to the present invention. As can be seen from these figures, the dryer 10 according to the present invention includes a drying chamber 11 for drying a dry matter, and the air suctioned on the outer upper surface of the dryer 10 is primarily heated by solar radiation. The solar radiation plate 20 is provided so that it can be carried out.

One side of the solar radiation plate 20 is formed with an air inlet 21 for sucking air, the cross-sectional shape of the solar radiation plate 20 is formed in a wave shape. In addition, a plurality of suction holes 23 are formed on the surface thereof to suck solar radiation heat generated from the surface of the solar radiation plate 20.

The back of the dryer 10 is provided with a panel 27 having a plurality of air inlets 25 perforated to uniform the flow rate distribution of air. Then, one end of the duct 30 is connected to the lower surface of the solar radiation plate 20, and the other end is connected to the panel 27 installed at the rear of the dryer 10 to guide the air toward the drying chamber 11.

The burner 31 is installed inside the duct 30 so as to heat the air supplied by the solar radiation plate 20 to the second heat to further heat and dry.

Here, the solar radiation generated by the solar radiation plate 20 is sucked through the suction damper 40 and the suction force is possible by the fan 33 installed in front of the burner 31.

On the other hand, the discharge duct 50 is provided in front of the drying chamber 11 to discharge the air inside the drying chamber 11 to the outside of the dryer as needed. In addition, the discharge duct 50 is provided with an intermediate damper 51 and a discharge damper 53 at predetermined intervals so that the air inside the drying chamber 11 can be properly discharged and guided to the outside of the dryer 10. One end of 50 is provided with a discharge port 55 for discharging air.

In addition, by installing a bypass damper (57) in communication with the upper side of the front region of the drying chamber 11 and the duct (30), the high-temperature, high-humidity air is introduced into the dryer (10) to dry the dried material and discharged, the solar radiation plate While passing through the lower heat recovery surface 29 of (20) to recover the heat by the heat exchange with the introduced air to reduce the energy.

In the dryer 10 according to the present invention configured as described above, the air sucked through the suction hole 23 of the solar radiation plate 20 mounted above the drying chamber 11 is primarily heated by the solar radiation heat.

The air heated by the solar radiation plate 20 is sucked by the fan 33 installed in the duct 30, and the sucked air is controlled by the suction damper 40 to the burner 31 installed in the duct 30. By secondary heating.

The air heated second by the burner 31 is further heated and dried to flow into the drying chamber 11 through the suction hole 23 of the panel 27 at a uniform flow rate.

The air introduced into the drying chamber 11 consumes energy by recovering the heat by heat exchange with the air introduced while the hot and humid air discharged after drying the dry matter passes through the heat recovery surface 29 under the solar radiation plate 20. Will be reduced.

Here, the suction damper 40, the intermediate damper 51, the discharge damper 53 and the bypass damper 57 installed in the duct 30 and the discharge duct 50 is a detector (not shown) for detecting the temperature inside the duct, etc. And the control unit for controlling the signal, so that the drying environment can be controlled according to the type and condition of the building.

As described above, according to the present invention, since the intake air is more efficient than the conventional hot air dryer by the solar radiation heat energy obtained by passing through the solar radiation plate and the energy recovered from the heat recovery surface, it is arranged under the same dry heat load conditions required for drying. It is possible to expect to reduce fuel consumption by the amount of heat additionally obtained from recovery and solar radiation and to provide a dryer that can control the drying environment in accordance with the condition and type of building by adjusting the damper in the duct.

Claims (6)

A dryer having a burner and a drying chamber to generate hot air to dry a dried product, The dryer includes a solar radiation plate which is positioned along the longitudinal direction on the outer upper surface of the dryer and has an air inlet on one side and is configured to primaryly heat the sucked air by solar radiation heat; A panel installed on the rear wall of the dryer and having a plurality of suction holes to uniform the flow rate distribution of the air introduced therein; A duct connected from a lower surface of the solar radiation plate and connected to a panel side installed at the rear of the dryer and guiding the first heated air by the solar radiation plate to the drying chamber side; And a discharge duct installed in front of the drying chamber and discharging air in the drying chamber to the outside of the dryer. The method of claim 1, The solar radiation plate is And a plurality of suction holes formed on the surface of the solar radiation plate and absorbing the solar radiation heat. The method of claim 1, The duct is A suction damper for sucking in solar radiation generated by the solar radiation plate; A fan for guiding suction to the drying chamber through the suction damper; And a burner further drying the air sucked by the fan at a higher temperature. The method of claim 1, The discharge duct is And an intermediate damper and a discharge damper for guiding discharge of air in the drying chamber, wherein the discharge duct has an outlet at one end. The method of claim 1, The dryer And a bypass damper for connecting the upper surface of the front region of the drying chamber to the duct. The method of claim 1, The solar radiation plate is Dryer, characterized in that installed inclined at a predetermined angle toward the other side starting from one side in the longitudinal direction of the dryer.