ALL WEATHER PASSIVE-TYPE SOLAR OGAKO DRYING HOUSE

Abstract

In application of a green-house effect, under such a concept as to collect solar energy passively into the house and to exhaust moist air passively from the house, an all weather passive-type solar Ogako drying house H which is available for all day through a year was made up improving an agricultural vinyl-house in which Ogako is dried continuously during carriage on the belt conveyors 4, 5 due to solar energy and auxiliary heat, and then moist air yielded when drying Ogako is exhausted through an insulated cylinder 13. In this case, Ogako means sawdust or tipped small particles of wood which is raw material in order to produce a woody pellet fuel.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is front view of all weather passive-type solar Ogako drying house

FIG. 2 is plan view of all weather passive-type solar Ogako drying house

FIG. 3( a) is side view of all weather passive-type solar Ogako drying house including the inside equipped components

FIG. 3( b) is plan view of all weather passive-type solar Ogako drying house including the inside equipped components

FIG. 4( a) is an inner plan viewed from bottom of detailed top radiation panel

FIG. 4( b) is A-A cross-sectional and side views of FIG. 4(a)

FIG. 5 Enlarged plan view of the turn-back table with surroundings

FIG. 6( a) is plan of the turn-back table

FIG. 6( b) Side view of the turn-back table

FIG. 7( a) Side view of the rotational mixing scraper

FIG. 7( b) Plan view of the rotational mixing scraper

BEST MODE OF THE EMBODIMENT

According to the attached Figs, an executive example can be explained as follows:

As shown in front view of FIG. 1 and plan view of FIG. 2, the proper body of the drying house H like a Quonset hut constructed on a concrete floor 2 in depth direction, and covered with a double transparent film 1 and an open-close-type shading sheet 1′ inside the house. Solar radiation S permeates the double transparent film 1 and enters fully into the house H in daytime, while in night, the inside of roof and south surfaces of the house H is shut down with the open-close-type shading sheet 1′ to obstruct heat loss from the house. In this case, to raise up the green-house effect and the working performance, the double transparent film 1 may be changed to a triple transparent film.

The double transparent film 1 consists of the first layer film (trade name/F-CLEAN Natural Ray, thickness 60μ, material/fluorine resin series, made by ASAHI GLASS GREEN-TECH Corporation), second layer film (trade name/ACHILLES SOLAR CLEAN-IRODORI, thickness/0.13 mm, material/poly-vinyl chloride series, made by Achilles Corporation) in the embodiment. Any kinds of transparent film may be used as the double transparent film 1.

The shading sheet 1′ is a breathable plain sheet woven of a reed-shape film laminated of poly-vinyl chloride (black) and aluminum foil (trade name/Daionet, trade number/No.1212 (black), made by Dio Chemicals Corporation) in the embodiment.

The insulated cylinder 13 with take-out damper duct 12′ which exhaust passively moist air inside the house is settled outside north surface of the house H, take-in damper ducts 12 and shutter windows 14 are set up one by one on the west surface and the east surface each, besides the entrance 1E is provided on the west surface of the house for carrying in and out the lumber.

Two belt conveyors of a go-ahead conveyor 4 and a go-back conveyor 5 of 10 m length and 900 m width each, are installed inside the house H, and both of a slide-type top radiation panel 10′ and a fixed-type top radiation panel 10 heated with steam in high temperature of 150° C. are set over the go-ahead conveyor 154 and the go-back conveyor 5 in each.

Concerning the operation method on the top radiation panels 10, 10′, the fixed-type top radiation panel 10 which is always hung on about 600 mm over the go-back conveyor 5 is available in daytime, while the slide-type top radiation panel 10′ which is also hung on about 600 mm over the go-ahead conveyor 4 can be slid in north-south direction being available in night or heavy cloudy day too. In daytime, the slide-type top radiation panel 10′ can be slid until 600 mm (max) in north side as a scheme 10″, so that permeated solar radiation R can be directly incident on the go-ahead conveyor 4 without any shading. Both of the belt-conveyors 4, 5 move with slow speed of 10 m/h (=0.167 m/min).

Though in substitution for the slide-type top radiation panel 10′ a day light reflection plate can be provided, the drying effect by which is less performed than using the slide-type top radiation panel 10′.

FIG. 3 shows a support frame 11, a hanger slide rail 11′ and the scheme 10″ when sliding the slide-type top radiation panel 10′ over the go-ahead conveyor 4. As shown in a left side view of FIG. 3(a) and a plan view of FIG. 3(b), the slide-type top radiation panel 10′ is hung from a hanger slide rail 11′ held by a support frame 11 which frames over the go-ahead conveyor 4 and go-back conveyor 5, the slide-type top radiation panel 10′ is hung from the hanger slide rail 11′, as to be able to slide in north-south direction through hanger jig and hanger roller, and the fixed-type top radiation panel 10 is hung always rigidly from the support frame 11.

Two of the top radiation panels 10, 10′ are arranged over every belt-conveyor of the go-ahead conveyor 4 and go-back conveyor 5 installed in east-west direction, and have an inlet header 18 on the feed side, four steam pipes 17 on the radiation plate 16 and an outlet steam header 18′ on the return side each, through which steam of high temperature flows.

Around the top radiation panel, steam of 150° C. is supplied from a steam boiler (not shown in FIGs) to the inlet header 18 through a flexible steam pipe 18″, from the inlet header 18 to the steam pips 17 and then recovered into the outlet header 18′, after that the steam is returned to hot water boiler through another flexible steam pipe.

To power up the system capacity for the use in night, the top radiation panel on which steam pipe is increased from two to four is shown in FIG. 4. As shown in FIG. 4(a) an inner plan viewed from bottom, and FIG. 4(b) A-A line cross-sectional view and the side view, four steam pipes 17 are welded by means of spot welding 17′ on a radiation panel plate 16 in parallel, which is hung by a hanger jig 19 and a hanger roller 19′ from the hanger slide rail 11′. An angle bar 19″ is welded between a radiation panel plate 16 and a hanger jig 19 to connect both and reinforce enforce the radiation panel plate 16.

Inner surface of the radiation panel plate 16 with fin plate 16′ is coated in black as to increase thermal radiation from which, to be able to dry out Ogako even in night and on heavy cloudy day.

A turn-back table 6 with surroundings and details of the turn-back table 6 are shown in an enlarged plan of FIG. 5 and in a plan view of FIG. 6(a) and a side view of FIG. 6(b), a circular rotating table 6 composed of compiled wood panel and a circular gum sheet 21 is held freely around a vertical rotation axis 22 with a rotational bearing 23. A gum ring plate 21′ is fixed adhesively on periphery of under surface of the circular rotating table 6 at which the table is supported by four rollers 24, 25. Three idle rollers 24 of which support the table and a driving roller 25 of which drives the table in contact with the gum ring plate 21′ through a reduction gear 27 by a electric motor 26. The turn-back table 6 is rotated slowly counterclockwise by means of the driving roller 25 drived by the electric motor 26 through the reduction gear 27. As shown in the FIG. 5, a half dried Ogako on the turn-back table 6 fed from the go-ahead conveyor 4 through a saucer shoot 9 is transferred through another saucer-plate 9′ to the go-back conveyor 5.

A half dried Ogako is raked off by a scraper 6′ to another saucer-plate 9′ at start point of the go-back conveyor 5, and transferred on the go-back conveyor 5 with uniform thickness. After the half dried Ogako on the go-back conveyor 5 was fully died absorbing radiation from a top radiation panel 10, it can be recovered into a receive hopper 8 at end point of the go-back conveyor 5 as the production of fully dried Ogako.

Details of a rotational mixing scraper 20 are shown in FIG. 7. As shown in side view of FIG. 7(a) and plan of FIG. 7(b), the rotational mixing scraper 20 which is held freely by two bearings 28 through a rotational axis 29, is set on bridging the side frame of the go-ahead conveyor 4 and go-back conveyor 5, on which four of the blade 30 extended to radial direction from the rotational axis 29 and the same number of nails 31 as above fixed in opposite to the progress direction of the conveyors.

When Ogako is carried on the go-ahead conveyor 4 and go-back conveyor 5, the rotational mixing scraper 20 can be attached on as two sets a 10 m conveyor each, and rotated oppositely to progressing direction of both conveyors 4, 5, so that mixing and drying of Ogako are well done. Namely, the approaching-Ogako is scraped up by a nail 31 fixed on the blade of rotational mixing scraper 20, and put it on the blade surface, after passing a top dead center the Ogako is dropped on a rear surface of the forward blade due to its own gravity, and when rotating moreover the Ogako is transferred into the go-ahead conveyor 4 or go-back conveyor 5 as the going away-Ogako with mixing action. Besides, a guide plate 32 is set up to prevent scattering of Ogako from side frames of both conveyors 4, 5 when the rotational mixing scraper 20 works.

According to the attached FIGs, the operational and working methods on the all weather passive-type solar Ogako drying house H are explained as follows:

In daytime, a supply hopper 7 is placed at start point of a go-ahead conveyor 4 and a receive hopper 8 is placed at end point of a go-back conveyor 5, and raw Ogako is fed on the go-ahead conveyor 4 moving slow with uniform thickness from an outlet of the supply hopper 7, so that raw Ogako is dried absorbing direct solar radiation R permeated a double transparent film 1 such a scheme 10″ as the top radiation panel 10′ slid in north side of the house.

A saucer shoot 9 is set on the end point of the go-ahead conveyor 4, and Ogako is transferred into a turn-back table 6 after received in the saucer shoot 9 once. The turn-back table 6 which is rotated slow counterclockwise receives as half dried Ogako from the go-ahead conveyor 4, then half dried Ogako is raked off by a scraper 6′ to a saucer plate 9′ and fed to the go-back conveyor 5 with uniform thickness again. The half-dried Ogako is fully dried due to radiation from a fixed-type top radiation panel 10 over the go-back conveyor 5 and recovered into a receive hopper 8 at the end point of which as fully dried Ogako.

During Ogako carrying on both conveyors 4, 5, Ogako is mixed to accelerate the drying effect by means of a rotational mixing scraper 20, each conveyor 4, 5 can be set up two sets of the rotational mixing scraper 20. For this period in daytime, and during Ogako being carried on the go-ahead conveyor 4 and go-back conveyor 5, the Ogako is also dried by the convection owing to circulation of hot and low moist air inside the house by means of four small fans 15.

While in night or on heavy cloudy day, inside air is warmed up due to radiation and convection by means of the top radiation panels 10, 10′ and a floor heater 3 molded in the concrete floor 2 heated with an auxiliary boiler (out of Figs) to keep around 40° C. or so in the house H, and then raw Ogako on the go-ahead conveyor 4 is dried by means of a sliding-type top radiation panel 10′ pulled back in proper position of south side over which, and also half dried Ogako on a go-back conveyor 5 is dried by means of a fixed-type top radiation panel 10 over which by supplying high temperature steam (150° C.) from an auxiliary boiler respectively.

Claims

1. An all weather passive-type solar Ogako drying house improving an agricultural vinyl-house like a Quonset hut comprises of: a roof and walls of the house made of a double transparent film and a shading sheet,a floor of the house made of concrete,a floor heater molded in floor,two lines of belt conveyors installed in parallel each other along depth direction, one of which is a the go-ahead conveyor and the other is a go-back conveyor,a turn-back table connecting both the conveyors set up at the start point of the go-back conveyor,a supply hopper set on over the go-ahead conveyors and at start point, the west side end, of the go-ahead conveyors,a receive hopper set on under the end of go-back conveyor and lower level than that of the receive hopper, at end point, the east side end, of go-back conveyors,a saucer-shoot set on the end point of the go-ahead conveyor to receive Ogako from the conveyor,a saucer-plate set on the start point of the go-back conveyor to transfer Ogako to the go-back conveyor,a scraper on the turn-back plate set up at the start point of the go-back conveyor to rake off Ogako from the turn-back table to saucer-plate,a fixed-type top radiation panel and a slide-type top radiation panel hung on over the go-ahead and go-back conveyors respectively, besides,two insulated cylinders with take-out damper duct are settled in vertical north surface outside the house in which draft force is available.

2. All weather passive-type solar drying house according to claim 1, the shading sheet is opened to collect the solar energy in daytime and closed to obstruct heat loss in night by means of windlass spread up inside the double transparent film of the house.

3. All weather passive-type solar drying house according to claim 1, the rotational mixing scrapers held freely by two bearings through a rotational axis, are set on bridging the side frame of the go-ahead conveyor and go-back conveyor respectively.