JPH09173039A - Dryer for tobacco leaf using far infrared ray and drying of tobacco leaf using the dryer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a dryer for tobacco leaf having a reflecting face formed on the inside of a tobacco leaf housing part, free from danger of a fire and fear of evolution of a harmful gas, capable of shortening the number of drying days and stabilizing drying, by using far infrared rays. SOLUTION: This dryer for tobacco leaf is equipped with a tobacco leaf housing part 1 for storing tobacco leaves, a heat generating part 2 consisting of a heat source for emitting far infrared rays laid in the tobacco leaf housing part 1 and an air hole 17 for introducing an open air into the tobacco leaf housing part 1 and a covering material for covering the side and a ceiling face of the tobacco leaf housing part 1. The covering material has an exhaust port for exhausting from the tobacco leaf housing part 1 and a reflecting face 16 for reflecting a part of far infrared rays radiated from the heat source formed on the inside of the tobacco leaf housing part 1. The heat source is preferably equipped with a control part 21 for regulating the temperature and the action of the heat source.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a leaf tobacco drying apparatus using far infrared rays and a leaf tobacco drying method using the drying apparatus.

[0002]

2. Description of the Related Art Leaf tobacco is dried by a method of drying it for 4 to 5 days by using wind power like yellow seeds and a natural drying using a pipe house or a drying room like conventional seeds or Burley seeds. Can be roughly divided into

[0003] Recently, in the drying of conventional varieties or Burley varieties, improvement of the leaf tobacco drying method has been investigated because of the necessity of shortening the drying period, stabilizing the drying, reducing the production cost and reducing the drying management work. . A drying method using wind power such as yellow seeds has been studied, and a drying method using wind power has come to be used in the yellowing period and the mid-bone dry period, which have little influence on quality. The drier used here is a portable drier that blows warm air to the entire drier while moving through the drier, and a box-type drier used for drying yellow species. ^{There is} one that stores 100 to 120 kg of harvested leaf tobacco per ² and circulates warm air in the machine to dry (called "compact drying"). In each case, the heat obtained by burning kerosene with a burner is used as a heat source, and this is blown into the facility by a blower to dry the leaf tobacco.

However, in the case of drying conventional or Burley varieties, the original quality of the variety is cultivated by drying the leaf tobacco in a drying facility such as a pipe house or a wooden structure for a long period of time. When using drying that uses wind power, in order to maintain quality and suppress adverse effects on quality,
In addition to setting an upper limit on the drying temperature, we also set an upper limit on the air volume from the blower. In particular, with respect to the air volume, as the air volume increases, the drying is promoted, but the air volume to be blown is suppressed because the quality deteriorates, which causes problems such as ensuring a uniform drying process and shortening the drying period. There is.

In addition to the combustor, the dryer body to be used requires a blower and a duct for blowing or circulating hot air in the dryer, and a control device for appropriately operating them. It is an expensive dryer, and this is a factor that prevents the production cost of leaf tobacco from being reduced and spread.

[0006]

DISCLOSURE OF THE INVENTION The present invention is to solve the above-mentioned problems, and varieties such as conventional varieties or Burley varieties that exhibit original qualities by a drying method mainly based on natural drying. In order to reduce the number of drying days, stabilize drying, and suppress the deterioration of quality, a drying apparatus and a drying method using the drying apparatus are provided.

[0007]

The above problems can be solved by the following (1) a drying device using far infrared rays and (2) a method for drying leaf tobacco using the device.

(1) Drying device using far infrared rays A leaf tobacco containing portion for containing leaf tobacco, a heat source for emitting far infrared rays provided in the leaf tobacco containing portion for drying the leaf tobacco, and an outside air are introduced into the leaf tobacco containing portion. A heat generating part consisting of a vent for doing so, and a cover for covering the side surface and the ceiling surface of the leaf tobacco storage part, the cover having an exhaust port for exhausting from the leaf tobacco storage part, and from the heat source. A leaf tobacco drying apparatus using far infrared rays, which has a reflecting surface formed on an inner surface of the leaf tobacco storage part for reflecting at least a part of the emitted far infrared rays and radiating the far tobacco to the leaf tobacco.

The heat source may be provided with a control unit for controlling the temperature and operation of the heat source.

Further, the leaf tobacco container may be provided with an observation window for observing the leaf tobacco contained in the leaf tobacco container.

(2) Method for Drying Leaf Tobacco A method for drying leaf tobacco using the above leaf tobacco drying apparatus, wherein far infrared rays are directly radiated by a heat source provided in a leaf tobacco housing portion, and at least a part of the far infrared rays is emitted. It is reflected by a reflection surface formed on the inner surface of the leaf tobacco storage unit, and by radiating the far infrared rays, the leaf tobacco in the storage unit is dried by far infrared rays, and the water evaporated from the leaf tobacco is stored in the leaf tobacco storage unit. A method of drying leaf tobacco that is discharged from the provided exhaust port.

[0012] Further, it is preferable that the above-mentioned leaf tobacco drying method is carried out by repeating a cycle of intermittent drying between days and rest at night.

Further, in the leaf tobacco drying method which can be used for drying the middle bones, it is preferable to dry the leaf tobacco stored in the leaf tobacco storage portion at a temperature of 40 ° C to 45 ° C.

When the above-mentioned leaf tobacco drying apparatus is provided with a control unit, it is preferable that the cycle of the above-mentioned day-intermittent drying-night rest cycle and the temperature control of 40 ° C. to 45 ° C. be performed by this control unit.

The drying apparatus using far infrared rays according to the present invention will be described below.

The far-infrared ray drying apparatus of the present invention comprises a leaf tobacco storage portion, a heat generating portion provided in the lower part of the leaf tobacco storage portion, and a cover for covering the leaf tobacco storage portion.

The far-infrared ray drying apparatus of the present invention accommodates leaf tobacco, and an accommodating section for drying the leaf tobacco can accommodate leaf tobacco.
Any material may be used as long as it can be efficiently dried. For example, an L-shaped angle assembled into a rectangular parallelepiped can be given as an example. Further, the leaf tobacco storage portion is provided with a means for supporting the hanging tool so that the hanging tool holding the leaf tobacco can be hung. This means
For example, there is an L-shaped shelf angle or the like provided on the side surface of the leaf tobacco accommodating portion so as to support both ends of a steel hanger that holds the leaf tobacco. The means for supporting the hanger such as the steel hanger depends on the height of the leaf tobacco storage part,
The number of stages is preferably 1 to 3 from the viewpoint of far infrared ray efficiency and the like. The step interval is set according to the length of leaf tobacco of the type to be dried.

The heat generating portion has a heat source for emitting far infrared rays and a vent for intake. As the heat source, a heater that emits far infrared rays such as a ceramic heater can be used. The present invention is a device that can directly heat and dry leaf tobacco without using kerosene. Further, as will be described later, the leaf tobacco drying apparatus of the present invention can be dehumidified by natural convection without forced blowing because an exhaust port is provided in the cover that covers the container.

In the far-infrared ray drying apparatus, the side surface and the ceiling surface of the leaf tobacco accommodating portion are covered with a coating body whose inner surface is vapor-deposited with aluminum. The coating may be a film or plate-shaped product obtained by vapor deposition of aluminum, and for example, a product obtained by vapor deposition of aluminum on vinyl or corrugated board can be used. The cover is provided with an exhaust port at the upper part of the side surface so that the exhaust from the upper part of the leaf tobacco accommodating part is emitted when the covering is attached to the leaf tobacco accommodating part. It is preferable that an observation window for observing the dry state of leaf tobacco is provided in the covering in a portion corresponding to one side surface of the accommodating portion. Furthermore, it is advisable to provide a loading / unloading surface on one side for loading / unloading a hanging tool such as a steel hanger that holds leaf tobacco.

Further, the far-infrared ray drying device of the present invention may be provided with moving means such as casters so that it can be moved.

Unlike the conventional dryer, the far-infrared dryer thus constructed needs to be equipped with a burner, a blower, a duct, and other necessary equipment for burning kerosene in the drying of leaf tobacco of conventional or Burley varieties. Since there is no blower, there is no noise, and because kerosene is not used as fuel, there is no risk of fire or the generation of harmful gas. Furthermore, the device of the present invention does not require the above-mentioned extra device and can use a lightweight material such as vinyl or corrugated cardboard for the covering body, so that the weight of the entire device can be reduced. Therefore, the equipment itself can be easily moved by mounting casters or the like.

Next, a method for drying leaf tobacco using the far infrared ray drying apparatus of the present invention will be described.

The method for drying leaf tobacco by the far-infrared ray drying apparatus of the present invention is suitable for leaf tobacco drying of a type such as a conventional type or a Burley type which mainly performs natural drying, and is particularly effective in drying the middle bones. For example, as described in the prior art, the drying method of the present invention using the far-infrared drying device is applied to the mid-bone drying instead of the natural drying in the mid-bone drying of the Burley type or the drying method using the wind power. can do.

In the method for drying leaf tobacco of the present invention, the far-infrared ray drying apparatus having the above-described structure suspends the leaf tobacco in the leaf tobacco storage portion with a suspending tool such as a steel hanger having the leaf tobacco sandwiched between 40 to 45 during the day. Intermittent drying is performed in which drying and resting at a temperature of ℃ are alternately repeated at regular intervals (2 to 3 hours), and resting at night is repeated (intermittent day-night resting). This allows the leaf tobacco to be dried under mild operating conditions.

In the drying method of the present invention, the drying temperature is
The above temperature range of 40 to 45 ° C. is preferred. When the drying temperature is low, the number of drying days is not significantly shortened. At temperatures other than this range, the quality of leaf tobacco, especially,
There is an effect on the flavor and taste.

The time required for drying the middle bones in the above temperature range varies depending on the position in the case of Burley seeds, but for example in the case of the later-described joint leaves it takes a period of 11 to 14 days Mid-bone dry results). Further, the drying temperature can be set to be about 5 ° C. higher than the mid-bone drying in the compact drying utilizing wind power. The drying method of the present invention may take a longer number of drying days as compared with the compact drying without blowing air, but the temperature can be set higher than that of the compact drying by about 5 ° C., so that the drying can be efficiently performed. Furthermore, the drying method of the present invention can increase the temperature setting as compared with the conventional method,
Does not affect the quality of leaf tobacco.

The leaf tobacco drying method using far infrared rays according to the present invention is most suitable for drying the middle bones, but it is also used for the yellowing stage drying for drying the leaf tobacco after harvesting which has a water content of about 90%. Is possible. When drying during the yellowing period, a large amount of water is discharged, so it is indispensable to use a blower that forcibly discharges it.However, even in this case, far infrared rays such as a ceramic heater should be used as the heat source of the dryer. It is possible.

[0028]

The far-infrared ray drying apparatus of the present invention comprises a leaf tobacco storage portion, a heat source provided at the lower portion of the leaf tobacco storage portion for emitting far infrared rays, and a heat generating portion having an intake port for inhaling the leaf tobacco storage portion. The far-infrared drying device is characterized in that a side surface and a ceiling surface of the portion are covered with a coating body formed by vapor deposition of aluminum, and the coating body is provided with an observation window and an opening for ventilation. Since this apparatus uses aluminum vapor-deposited on the covering in order to improve the radiation of far infrared rays, far infrared rays can be intensively emitted to leaf tobacco.

The far-infrared ray drying device having the above-mentioned structure is used to dry the middle bones of leaf tobacco of, for example, Burley. Drying is carried out until the medium bones of the leaf tobacco are dried by accommodating the leaf browned tobacco and drying temperature in the range of 40 to 45 ° C. and repeating intermittent drying during the day-resting cycle at night. It is done by doing.

Dehumidification is performed as follows. Far infrared rays of 3 to 7 microns are radiated from the heating portion, and this radiation is absorbed by leaf tobacco. The far-infrared rays absorbed by the leaf tobacco violently vibrate in resonance with the water molecules, generating heat and evaporating water. Fresh air outside the machine is taken in by using natural convection from the intake port for intake provided in the heat generating part of the far infrared drying device of the present invention. When the fresh air rises between the leaf tobacco in the accommodating unit, it accompanies the water evaporated from the leaves, and the vent for ventilation provided in the covering (this vent is located on the side surface near the ceiling surface of the leaf tobacco accommodating unit). (Provided) is exhausted, whereby the leaf tobacco is dried (dehydrated).

[0031]

BEST MODE FOR CARRYING OUT THE INVENTION

<Embodiment 1> Hereinafter, the far-infrared ray drying device of the present invention will be specifically described with reference to the drawings.

FIG. 1 is a schematic view showing one mode of the apparatus (accommodation section) of the present invention.

As shown, the device of the present invention comprises a strut 1
0, the ceiling angle 11 and the connecting angle 12, the leaf tobacco storage unit 1 assembled into a rectangular parallelepiped shape, and the heat generating unit 2 installed on the bottom surface thereof. As shown in the figure, the leaf tobacco storage unit 1 includes a support 1 which is an L-shaped shelf angle formed at an upper portion and an intermediate portion of a column 10 and on one side surface and the opposite side surface of the leaf tobacco storage unit 1.
3 is provided. The support 13 is installed on the upper and middle portions of the support column 10 so that the leaf tobacco is efficiently dried.
For example, the leaf tobacco is accommodated in the leaf tobacco accommodating portion 1 by holding both ends of a suspending tool 14 such as a steel hanger that holds the leaf tobacco therebetween.

The heat generating part 2 is provided with a heat source 3 composed of a heater 15 and a reflecting plate 16 and a ventilation hole 17 (see FIG. 2), and further, the upper surface mesh 1 provided on the upper part of the heat generating plate.
It is constituted by a heater frame 20 having an opening 19 having eight. The heater 15 of the heat source 3 is a heater that emits far-infrared rays, and is a planar ceramic far-infrared heater (for example, a custom-made product of Infrastein (500 W):
Daiken Denki Co., Ltd.) can be used. The heater is controlled by the controller 21. In this embodiment, two heaters 15 are installed on the reflection plate 16 (700 × 700 mm for two heaters), and the heater frame 20 has a bottom 4
4 pieces are evenly installed in each (FIGS. 1 and 2). Reflector 16
Any material that reflects far infrared rays can be used, and an aluminum plate or the like can be preferably used (in this embodiment, 800 ×
800mm aluminum plate was used). Further, as shown in FIG. 2, the ventilation port 17 for taking in outside air is provided with the heat source 3
In the vicinity of. Thereby, fresh air can be introduced efficiently. It is preferable to provide the same number of vent holes 17 corresponding to the heat sources. That is, in this aspect, 4
Two vents 17 were installed. The shape of the vent hole 17 is not particularly limited (the circular shape is shown in this embodiment). Further, the size of the vent hole 17 is 50 mm in the case of this embodiment.
The circular shape is preferred.

The opening 19 provided in the upper part of the heat source 3 is for passing far infrared rays and the air taken in from the ventilation hole 17, and the opening 19 is covered by the upper surface net 18. As the upper surface net 18, an iron net can be preferably used. The opening 19 preferably has the same size as the heat source 3 arranged in the heater frame bottom 4 in order to efficiently irradiate and ventilate far infrared rays.

The leaf tobacco accommodating portion 1 having the above structure is covered with the covering body shown in FIG. In this embodiment, a vinyl coating film 5 is used as the coating, and the inside of the coating film is vapor-deposited with aluminum or the like that reflects far infrared rays. As shown in the figure, the coating film 5 is provided with an exhaust port 22 for exhausting gas on the upper surface of each surface of the coating film 5, and an observation window 23 for observing the dry state of leaf tobacco on one side surface of the container. In this embodiment, seven exhaust ports are provided on each surface and are circular with a diameter of about 50 mm. The observation window is sealed with transparent vinyl on the inside, the outside is covered with the covering film 5, and an adhesive means such as a velcro tape is provided so as not to lower the heating efficiency by far infrared rays. Further, the coating film 5 is configured such that one side surface of the coating film is opened in order to make it easier to store or take out leaf tobacco. The opening can be joined to the other surface of the coating film by a joining means 24 such as a fastener.

The size of the drying device (housing part 1) of the present invention varies depending on the heat source used, but in the above-mentioned embodiment using eight ceramic heaters (500 W) as the heat source, the height is 2000 mm to 2500 mm and the width is 1800 mm. 190
0 mm and a depth of 1800 mm to 1900 mm are preferable.
Further, in the heater frame 20 of the heat generating portion 2, the height is 200 mm to 250 mm, the width is 1800 mm to 1900 mm, and the depth is 1.
800 mm to 1900 mm is preferred. Further, in the above aspect, the size of the coating film 5 is the same as that of the accommodating portion,
The observation window has a size of about 200 mm to 1200 mm.

In the drying device of the present invention, as shown in FIG. 1, the caster 25 and the adjuster 2 are provided at the bottom of the device.
6 can be provided to facilitate movement and fixation of the device.

In this embodiment, the most suitable leaf tobacco is stored in two stages and dried, but the present invention is not limited to this. Therefore, various sizes can be taken according to the ability of the heater.

<Embodiment 2> Next, the method for drying leaf tobacco of the present invention will be described.

An example of performing mid-bone drying of Burley seed leaf tobacco using the leaf tobacco drying apparatus using far infrared rays having the above-described structure will be described.

For the drying, the leaf tobacco, which has been browned, is stored in the upper and lower two stages in the storage part of the far infrared drying device having the above-mentioned structure, and the drying temperature is 40 ° C. to 45 ° C., and the cycle of intermittent drying between days and night is repeated. , The leaf tobacco was operated until it was dried.

According to the drying method of the present invention, it is possible to remove 3
Far infrared radiation of ~ 7 microns is emitted, which is absorbed by the tobacco leaf. The water molecules and far infrared rays violently vibrate and vibrate, causing heat to evaporate water, and fresh air is taken in from the outside by natural convection from the intake port for air intake provided in the heat generation part of the dryer, and it evaporates from the leaves. The moisture-containing air is discharged from the exhaust port provided on the upper portion of the coating film 5 for exhaust, so that the moisture is removed. This accelerates the drying (dehydration) of leaf tobacco.

The following is an example in which Burley seed tobacco was used and the drying apparatus of the present invention was used for drying the middle bones, together with the results when compared with the compact drying method and the natural drying method.

[0045]

【Example】

(Example 1) In this example, burley seed leaf tobacco was subjected to middle bone drying under the conditions shown in Table 1.

[0046]

[Table 1]

The drying apparatus of the present invention used for drying the inner bones was suspended in two stages of 3.3 m ² (8.6 m ³ ), and the heat generating part had eight 500 W planar ceramic heaters arranged under the drying apparatus. It has the structure of Embodiment 1 (Table 1: groups 2 to 4). In addition, a small experimental dryer having the same function as that of the compact dryer which is becoming popular in the Burley seed tobacco production area was used for the middle bone drying in the first ward of Table 1 (hereinafter referred to as "compact drying"). . Also,
In the 5th ward, a conventional drying method using a pipe house and a wooden drying room was set as a standard section.

In both compact drying and far-infrared drying, a steel hanger was used as a suspending tool, and the suspending amount was the conventional suspending amount (see the conditions in Table 1) (hereinafter the same).

Dry sitting tobacco is performed on the middle leaf,
The number of days required for drying is also shown in Table 1.

In compact drying, the number of drying days was 7 days, but in drying using the drying apparatus of the present invention, it took 6 to 9 days depending on the set temperature.

Table 2 shows the results of comparing the appearance quality of dried dry leaves with those of 5 groups (natural drying: standard group).

[0052]

[Table 2]

The comparison of the appearance quality from the appearance property was in the order of 5 wards ≧ 2 wards> 3 wards ≧ 1 wards> 4 wards. From the appearance comments in the table, leaf tobacco dried by far-infrared ray drying showed a more subdued hue than compact drying, and the leaf quality was excellent such that the leaf quality was soft, and showed the same quality as natural drying. However, in the drying using far infrared rays, the leaf tip tends to become brighter as the temperature rises.
At ℃ (4 wards), although the number of drying days was short, brittleness was observed, indicating that the quality was poor.

Next, Table 3 shows the comments for each section of the taste quality evaluation.

[0055]

[Table 3]

Regarding the quality of taste, natural drying was preferred, followed by far infrared drying and compact drying.

Regarding the drying temperature by far infrared drying,
In far-infrared drying, at a high temperature such as 50 ° C., drying is accelerated, but both appearance and taste quality are 40 ° C.,
The quality is lower than 45 ° C. Therefore, the upper limit temperature is 45
It was considered preferable to set the temperature up to ° C.

The arrows to the right of the numerical values in the table mean slightly better (upward arrows) or slightly worse (downward arrows) than the numerical values (the same applies hereinafter).

(Example 2) Next, the drying was examined by the difference in the operating conditions of the drying.

In this example, the middle bones of Burley seed tobacco were dried under the conditions shown in Table 4.

[Table 4]

Table 5 shows the number of processing days for each distinction under the conditions of Table 4.
Tables 6 and 7 show the comments regarding the appearance property quality evaluation and the taste quality evaluation of each distinction.

[0062]

[Table 5]

[0063]

[Table 6]

[0064]

[Table 7]

Regarding the quality, the 3rd section showed a quality similar to or close to the natural drying of the 5th section, and the 4th section was inferior in quality in the order of the 2nd section and the 3rd section.

From this, as for the drying method, the drying method in the operation cycle of the day-intermittent drying and the night rest has a better quality than the drying in the compact drying and the far infrared ray drying (operating 12 hours-12 hours rest). The quality was almost the same as that of conventional natural drying. From the above results, in the far-infrared drying without blowing, the drying method in the operation cycle of (day-intermittent drying-resting at night) is most suitable, and it is possible to perform natural drying without lowering the appearance quality and taste quality of leaf tobacco. It can be seen that the equivalent leaf tobacco can be obtained.

(Example 3) Next, the conditions for intermittent drying were examined under the conditions shown in Table 8.

[0068]

[Table 8]

Table 9 shows the number of treatment days for each type of dried leaf tobacco under the conditions shown in Table 8, and Tables 10 and 11 show comments on the evaluation of appearance quality and taste quality.

[0070]

[Table 9]

[0071]

[Table 10]

[0072]

[Table 11]

In the drying under the same conditions as the compact drying (operating time 2 hours-resting 3 hours), the far infrared ray drying apparatus took 2 more days to dry. However, the 3 sections in which the operation time of the intermittent drying was 3 hours and the rest was 2 hours ended in about the same number of days as the compact drying. The appearance quality of the dried leaves was the same for both the 2nd and 3rd plots, and was closer to the natural drying of the 4th plot than the 1st plot. In comparison of taste quality, 1
The same was true for the 2nd and 3rd plots, and the 4th plot showed quality close to that of natural drying in the 3rd plot, followed by the 1st and 2nd plots.

From this, the operation of the intermittent drying was carried out from the cycle of (drying 2 hours-pause 3 hours) to (drying 3 hours-pause 2
It can be seen that the (time) cycle shows a quality closer to natural drying.

(Analysis of Content Components, etc.) Table 12 shows the physical properties of dry leaves and the analytical values of the content components. The dried leaves used in the analysis were those of Example 1.

[0076]

[Table 12]

The puffability and fragility index show the physical properties of leaf tobacco and show the ease of use as a raw material. The smaller the puffiness is, the better it is. It shows difficult properties. Also,
The total volatile base and nicotine content are also analyzed as indicators of the content components.

Regarding the physical properties and content components, no clear difference was observed between the groups, but regarding the total volatile base content and nicotine content, the far-infrared-dried ones showed slightly higher numerical values than the others. However, this is due to the fact that the content components also decrease with compact drying due to the rapid dehydration due to the air volume, and in the case of natural drying, the content components decreased due to the prolonged drying days. Conceivable.

Table 13 shows the measured values of the cross-sectional structure of dry leaves.

[0080]

[Table 13]

From the viewpoint of the leaf thickness and the void ratio of the dry leaf tissue structure, it is understood that the dry leaf tobacco by far infrared rays has a tissue structure close to that between compact drying and natural drying.

Next, Table 14 shows the measurement results of the content of solanone, which is a lipid component of dry leaves, which is said to have a high correlation with the taste quality.

[0083]

[Table 14]

3 of solanone, norsolazinone and DVT
The taste quality is estimated by the amount of one component and the ratio of these three components, and it is said that the larger the numerical value, the better the taste. The far-infrared-dried product had a higher value than the compact-dried product, showing a content close to that in natural drying. From this result, it can be estimated that the taste quality is in the order of natural drying> far infrared drying> compact drying.

From the above results, it was found that in the mid-bone drying method of leaf tobacco using far infrared rays, dried leaf tobacco closer to natural drying than compact drying can be obtained.

[0086]

INDUSTRIAL APPLICABILITY The far-infrared ray drying apparatus of the present invention irradiates far-infrared rays from a ceramic heater as a heat source to dry leaf tobacco, and by removing moisture by natural convection, compact drying is achieved. In addition, the leaf tobacco is dried without forced air blow using a blower. In particular, it can be used for the drying of the middle bones, which is a type of leaf tobacco drying by natural drying such as Burley.

Further, since far infrared rays from a ceramic heater are used as a heat source, there is no danger of fire or generation of harmful gas. Further, since no blower is used, there is no concern about noise.

In the method for drying leaf tobacco by the far-infrared ray drying apparatus of the present invention, the leaf tobacco can be dried under mild operating conditions by intermittent drying during the day and rest at night. Therefore, drying control by temperature and humidity such as Burley type is suitable for drying in a type that may affect the quality. In addition, the drying method of the present invention is 5 ° C. higher than the conventional one because the operating conditions are relaxed as described above.
Even if the temperature is raised to 5 ° C, there is little influence on the quality and the efficiency can be improved.

The far-infrared ray drying apparatus of the present invention does not need to be equipped with a blower and a duct, and the side surface and the covering surface of the ceiling can be made of a vinyl coating film, so that the weight can be reduced. Therefore, it is possible to easily move the drying device itself by equipping a moving means such as a caster.

[Brief description of the drawings]

FIG. 1 is a schematic view showing an aspect of a housing portion of a far infrared ray drying device of the present invention.

FIG. 2 is a schematic view showing a heat generating part of the present invention in which a heat source composed of a heater and a reflector and a vent are installed.

FIG. 3 is a schematic view showing an embodiment of a coating film that covers a housing portion of the far infrared ray drying device of the present invention.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Leaf tobacco storage part, 2 ... Heat generation part, 3 ... Heat source, 4 ... Heater frame bottom part, 5 ... Coating film, 10 ... Strut, 11 ... Ceiling angle, 12 ... Connection angle, 13 ... Support body, 14 ... Steel hanger , 15 ... Heater, 16 ... Reflector, 17 ...
Vent hole, 18 ... Top net, 19 ... Opening part, 20 ... Heater frame, 21 ... Controller, 22 ... Exhaust port, 23 ... Observation window, 24 ... Fastener, 25 ... Caster, 26 ... Adjuster.

 ─────────────────────────────────────────────────── ─── Continuation of front page (72) Inventor Yoji Hori Morioka City, Iwate Prefecture Midorigaoka 2-31-1 Japan Tobacco Inc. Morioka Raw Materials Division Morioka Leaf Tobacco Technology Center

Claims (6)

[Claims] 1. A leaf tobacco storage unit for storing leaf tobacco, a heat source for emitting far infrared rays provided in the leaf tobacco storage unit for drying the leaf tobacco, and a vent for introducing outside air into the leaf tobacco storage unit. The heating unit includes a cover that covers the side surface and the ceiling surface of the leaf tobacco storage unit, the cover has an exhaust port for exhausting air from the leaf tobacco storage unit, and at least the far infrared rays radiated from the heat source. A leaf tobacco drying apparatus using far infrared rays, which has a reflecting surface formed on an inner surface of the leaf tobacco storage part for reflecting a part of the radiation and radiating the leaf tobacco. 2. The leaf tobacco drying apparatus using far infrared rays according to claim 1, wherein the heat source is provided with a control unit for controlling the temperature and operation of the heat source. 3. The leaf tobacco using far infrared rays according to claim 1, wherein the leaf tobacco storage portion is provided with an observation window for observing the leaf tobacco stored in the leaf tobacco storage portion. Drying device. 4. A leaf tobacco storage unit for storing leaf tobacco, a heat source for emitting far infrared rays provided in the leaf tobacco storage unit for drying the leaf tobacco, and a vent for introducing outside air into the leaf tobacco storage unit. The heating unit includes a cover that covers the side surface and the ceiling surface of the leaf tobacco storage unit, the cover has an exhaust port for exhausting air from the leaf tobacco storage unit, and at least the far infrared rays radiated from the heat source. A leaf tobacco drying method using a leaf tobacco drying device using far infrared rays, characterized in that it has a reflecting surface formed on an inner surface of the leaf tobacco storage part for reflecting a part and radiating to the leaf tobacco. A far-infrared ray is directly radiated by a heat source provided in the accommodation section, and at least a part of the far-infrared ray is accommodated in the leaf tobacco. The is reflected by the formed reflecting surface on the inner surface, by radiating the distal infrared, tobacco drying wherein the drying by far infrared leaf tobacco within the housing portion. 5. The method for drying leaf tobacco according to claim 4, wherein a cycle of intermittent drying between days and rest at night is repeated. 6. The method for drying leaf tobacco according to claim 4, wherein the leaf tobacco stored in the leaf tobacco storage portion is subjected to mid-bone drying of the leaf tobacco at a temperature of 40 ° C. to 45 ° C.