CN113955318B - Rare earth catalytic material stores transport case - Google Patents

Abstract

The invention belongs to the field of rare earth material transportation, and relates to a rare earth catalytic material storage and transportation box, which comprises a box body, wherein one side of the bottom of the box body is provided with a cover plate connecting groove, cover plate connecting shafts are symmetrically and fixedly arranged at two sides in the cover plate connecting groove, one end of each cover plate connecting shaft is slidably connected with a cover plate shaft, one side of each cover plate shaft is fixedly provided with a cover plate, the bottom of the box body is symmetrically provided with a plurality of box body horizontal rails along the width direction of the box body, the cover plate is symmetrically provided with a plurality of cover plate horizontal rails along the length direction of the cover plate, the cover plate horizontal rails and the box body horizontal rails can be communicated in a certain state, a horizontal shock absorption base is fixedly arranged at the joint of one side in the box body horizontal rails and the box body, a horizontal telescopic shell is fixedly arranged on the horizontal shock absorption base, and a horizontal telescopic rod is slidably arranged on the horizontal telescopic shell. The invention can facilitate the rare earth catalytic material to be taken out at any time and effectively reduce the damage of vibration to the material in the transportation process.

Description

Rare earth catalytic material stores transport case

Technical Field

The invention belongs to the field of rare earth material transportation, and particularly relates to a rare earth catalytic material storage and transportation box.

Background

Rare earth is a generic term for seventeen metallic elements, namely lanthanoid elements and scandium and yttrium in the periodic table. There are 250 rare earth ores in nature. The earliest rare earth was found by the finnish chemist, gatelin, 1794, who separated the first rare earth "element" from a piece of bitumen-like heavy ore. Since rare earth minerals were found in the 18 th century to be rare earth, only small amounts of water-insoluble oxides were produced by chemical methods at the time, and historically such oxides have been conventionally referred to as "earth" and are therefore known as rare earths.

The rare earth catalytic material in the United states accounts for about 57.6 percent of the total rare earth consumption, while the rare earth consumption in China is only about 8.5 percent, so that the unbalance current situation of rare earth use in China is changed, the great development of the rare earth catalytic material is significant, the existing rare earth material transportation device has single function and no damping and buffering function, is always in a sealed state during transportation, is inconvenient to take out during use, and is necessary to design

Disclosure of Invention

The invention aims at solving the problems in the prior art and provides a rare earth catalytic material storage and transportation box, which can facilitate the taking out of the rare earth catalytic material at any time and effectively reduce the damage of vibration to the material in the transportation process.

In order to achieve the above purpose, the present invention adopts the following technical scheme: the utility model provides a rare earth catalytic material stores transport case, includes the box, bottom half one side is equipped with the apron spread groove, apron spread groove both sides symmetry has set firmly the apron connecting axle in the apron connecting groove, the one end sliding connection of apron connecting axle has the apron axle, one side of apron axle has set firmly the apron, bottom half is equipped with a plurality of box horizontal track along box width direction symmetry, cover plate on the apron along cover plate length direction symmetry has a plurality of apron horizontal track, apron horizontal track and box horizontal track can be linked together under certain state, one side and box junction have set firmly the horizontal shock absorption base in the box horizontal track, horizontal telescopic housing has set firmly on the horizontal shock absorption base, horizontal telescopic housing sliding is equipped with the horizontal telescopic link, the output of horizontal telescopic link has set firmly horizontal buffer block, be connected with first spring between horizontal buffer block and the horizontal shock absorption base, sliding in the box horizontal track is equipped with a plurality of sliders.

Preferably, the bilateral symmetry has set firmly the flexible casing of shock attenuation on the slider, the slip is equipped with the shock attenuation telescopic link in the flexible casing of shock attenuation, slider upper end middle part is equipped with buffer spring, buffer spring's the other end is connected with the interior box of shock attenuation, box horizontal track passes through sealing connection membrane sealing connection with the orbital surface of apron level, the bottom has set firmly a plurality of supplementary flexible bases in the shock attenuation, supplementary flexible casing has been set firmly on the supplementary flexible base, supplementary flexible casing is internal to slide and is equipped with supplementary telescopic link, supplementary telescopic link's output has set firmly place the platform, place the both sides tip of platform and be equipped with the sliding connection pole, place the platform upper end middle part has set firmly the tombarthite and has placed the case, place platform upper end both sides tombarthite is placed the case and has been set firmly the stopper outward.

Preferably, one side of the two inner side walls of the shock absorption inner box body is provided with a moving groove, two side sliding connecting rods at one end of the placing platform slide in the moving groove, one side of the moving groove is provided with a limiting groove, two side sliding connecting rods at the other end of the placing platform slide on the rotating wheel, the rotating wheel slides in the limiting groove, one side of the bottom of the shock absorption inner box body is fixedly provided with a supporting rod, one end of the supporting rod is slidably connected with a rotating shaft, a belt pulley is fixedly arranged outside the rotating shaft, one side of the rotating shaft is fixedly provided with a gear, a belt is arranged outside the belt pulley, and a fixing rod is fixedly arranged on the vertical direction of the rotating wheel on the inner side wall of the shock absorption inner box body.

Preferably, the upper side slides in the shock attenuation interior box and is equipped with the movable plate, the one end slip of movable plate is equipped with the connecting axle, the outer sliding connection of connecting axle has the movable plate, repeats in proper order, the connecting axle sliding connection on the movable plate end has sealed sliding plate, the last magnetism that has set firmly of sealed sliding plate is inhaled the connecting block, the sealing membrane has set firmly with movable plate homonymy top in the shock attenuation interior box, the other end and the sealed sliding plate of sealing membrane link to each other, the magnetism is inhaled the connecting block and is set firmly in box lower extreme one side recess.

Preferably, a drying ventilation cavity is formed in one side above the box body, a drying filter box is arranged in the drying ventilation cavity, an input pipeline is fixedly arranged on one side of the drying filter box, one end of the input pipeline is communicated with the outside of the box body, a plurality of dehumidification plates are arranged on one side, close to the input pipeline, of the drying filter box in the width direction of the drying filter box, the dehumidification plates are connected through connecting plates, a filter screen is fixedly arranged on one side, far away from the input pipeline, of the dehumidification plates, a temperature return cavity is arranged on one side, far away from the filter screen, of the drying filter box, a heating pipe is arranged in the temperature return cavity, a fan base is arranged on one side, far away from the filter screen, of the temperature return cavity, a fan rotating shaft is connected to the middle part in the fan base in a sliding mode, and a fan is arranged outside the fan rotating shaft.

Preferably, a cylinder is fixedly arranged on one side, far away from the fan base, in the drying and filtering box, a drying particle plate is arranged on one side in the cylinder, a purifying plate is arranged on one side of the drying particle plate, an air outlet hole is formed in the inner bottom of the cylinder, a collecting box is fixedly arranged at one end of the cylinder, a spiral air cooling plate is arranged at a gap between the outer side of the collecting box and the drying and filtering box, and an air inlet is fixedly formed at one end of the drying and filtering box.

The beneficial effects are that:

1. the movable rail can be folded through relative rotation of the box body and the cover plate, the space occupied by the box body is greatly reduced, meanwhile, the cover plate can limit the rare earth containing device, and a certain force is applied to enable the containing device to be incapable of easily shaking inwards, so that the damping efficiency is greatly improved.

2. The gear drives a series of parts to move so that the holding device moves outwards and lifts, and the rare earth catalytic material is greatly convenient to take out and put back.

Drawings

Fig. 1 is a perspective view of the present invention.

Fig. 2 is a side view of the present invention.

Fig. 3 is a sectional view taken along the direction A-A in fig. 2.

Fig. 4 is a sectional view in the direction B-B of fig. 3.

Fig. 5 is a sectional view taken along the direction C-C in fig. 4.

Fig. 6 is a partial cross-sectional view taken along the direction D-D in fig. 3.

Fig. 7 is an enlarged view of the structure at E in fig. 4.

Fig. 8 is an enlarged view of the structure at F in fig. 3.

Fig. 9 is an enlarged view of the structure at G in fig. 3.

Fig. 10 is an enlarged view of the structure at H in fig. 3.

In the figure, a box 10, a cover plate connecting groove 11, a cover plate connecting shaft 12, a cover plate shaft 13, a cover plate 14, a box horizontal rail 15, a cover plate horizontal rail 16, a horizontal damping base 17, a horizontal telescopic housing 18, a horizontal telescopic rod 19, a horizontal damping block 20, a first spring 21, a sliding block 22, a damping telescopic housing 23, a damping telescopic rod 24, a damping spring 25, a sealing connecting film 26, a damping inner box 27, an auxiliary telescopic base 28, an auxiliary telescopic housing 29, an auxiliary telescopic rod 30, a placing platform 31, a rare earth placing box 32, a limiting block 33, a rotating wheel 34, a limiting plate 35, a moving groove 36, a limiting groove 37, a supporting rod 38, a rotating shaft 39, a belt pulley 40, a gear 41, a belt 42, a fixing rod 43, a moving plate 44, a connecting shaft 45, a sealing sliding plate 46, a sealing film 47, a magnetic suction connecting block 48, a drying cavity 49, a drying filter box 50, an input pipeline 51, a dehumidifying plate 52, a connecting plate 53, a filter screen 54, a back temperature cavity 55, a heating pipe 56, a fan base 57, a fan 58, a fan 59, a drying particle plate 60, a purifying plate 61, an air outlet 61, a vent 62, a spiral air inlet port 63, an air collecting box 64, an air inlet port 65 and an air intake port 65.

Detailed Description

The following are specific embodiments of the present invention and the technical solutions of the present invention will be further described with reference to the accompanying drawings, but the present invention is not limited to these embodiments.

In the description of the present invention, it should be noted that, the azimuth or positional relationship indicated by the terms "inner", "lower", etc. are based on the azimuth or positional relationship shown in the drawings, or the azimuth or positional relationship that the inventive product is conventionally put in use, are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the apparatus or elements referred to must have a specific azimuth, be configured and operated in a specific azimuth, and thus should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like, are used merely to distinguish between descriptions and should not be construed as indicating or implying relative importance.

As shown in fig. 1-10, a rare earth catalytic material storage and transportation box comprises a box body 10, a cover plate connecting groove 11 is formed in one side of the bottom of the box body 10, cover plate connecting shafts 12 are symmetrically and fixedly arranged on two sides in the cover plate connecting groove 11, one end of each cover plate connecting shaft 12 is slidably connected with a cover plate shaft 13, a cover plate 14 is fixedly arranged on one side of each cover plate shaft 13, a plurality of box body horizontal rails 15 are symmetrically arranged at the bottom of the box body 10 along the width direction of the box body 10, a plurality of cover plate horizontal rails 16 are symmetrically arranged on the cover plate 14 along the length direction of the cover plate 14, the cover plate horizontal rails 16 and the box body horizontal rails 15 can be communicated in a certain state, a horizontal vibration base 17 is fixedly arranged at the joint of one side in the box body horizontal rails 15 and the box body 10, a horizontal vibration buffering shell 18 is fixedly arranged on the horizontal vibration buffering base 17, a horizontal telescopic rod 19 is slidably arranged on one end of each horizontal telescopic shell 18, a horizontal buffering block 20 is fixedly arranged on the output end of each horizontal telescopic rod 19, a first spring 21 is connected between each horizontal buffering block 20 and each horizontal vibration base 17, and a plurality of sliding blocks 22 are slidably arranged in the box body horizontal rails 15.

Further, the shock-absorbing telescopic shell 23 is symmetrically fixed on two sides of the sliding block 22, the shock-absorbing telescopic rod 24 is slidably arranged in the shock-absorbing telescopic shell 23, the buffer spring 25 is arranged in the middle of the upper end of the sliding block 22, the other end of the buffer spring 25 is connected with the shock-absorbing inner box 27, the box horizontal rail 15 is in sealing connection with the outer surface of the cover plate horizontal rail 16 through the sealing connection film 26, a plurality of auxiliary telescopic bases 28 are fixedly arranged at the inner bottom of the shock-absorbing inner box 27, an auxiliary telescopic shell 29 is fixedly arranged on the auxiliary telescopic bases 28, an auxiliary telescopic rod 30 is slidably arranged in the auxiliary telescopic shell 29, a placing platform 31 is fixedly arranged at the output end of the auxiliary telescopic rod 30, sliding connecting rods are arranged at the end parts of two sides of the placing platform 31, a rare earth placing box 32 is fixedly arranged in the middle of the upper end of the placing platform 31, and a limiting block 33 is fixedly arranged outside the rare earth placing box 32 at two sides of the upper end of the placing platform 31.

Further, a moving groove 36 is formed in one side of two side walls in the shock absorption inner box 27, sliding connecting rods on two sides of one end of the placing platform 31 slide in the moving groove 36, a limiting groove 37 is formed in one side of the moving groove 36, rotating wheels 34 are arranged on sliding connecting rods on two sides of the other end of the placing platform 31, the rotating wheels 34 slide in the limiting groove 37, a supporting rod 38 is fixedly arranged on one side of the bottom of the shock absorption inner box 27, one end of the supporting rod 38 is slidably connected with a rotating shaft 39, a belt pulley 40 is fixedly arranged outside the rotating shaft 39, a gear 41 is fixedly arranged on one side of the rotating shaft 39, a belt 42 is arranged outside the belt pulley 40, and a fixing rod 43 is fixedly arranged on the inner side wall of the shock absorption inner box 27 in the vertical direction of the rotating wheels 34.

Further, a moving plate 44 is slidably arranged on one side of the upper portion in the shock absorption inner box 27, a connecting shaft 45 is slidably arranged at one end of the moving plate 44, the moving plate 44 is slidably connected outside the connecting shaft 45, the connecting shaft 45 on the tail end of the moving plate 44 is slidably connected with a sealing sliding plate 46, a magnetic connection block 48 is fixedly arranged on the sealing sliding plate 46, a sealing film 47 is fixedly arranged on the upper portion of the same side of the shock absorption inner box 27 as the moving plate 44, the other end of the sealing film 47 is connected with the sealing sliding plate 46, and the magnetic connection block 48 is fixedly arranged in a groove on one side of the lower end of the box 10.

Further, a drying ventilation cavity 49 is formed in one side above the box body 10, a drying filter box 50 is arranged in the drying ventilation cavity 49, an input pipeline 51 is fixedly arranged on one side of the drying filter box 50, one end of the input pipeline 51 is communicated with the outside of the box body 10, a plurality of dehumidification plates 52 are arranged on one side, close to the input pipeline 51, of the drying filter box 50 in the width direction of the drying filter box 50, the dehumidification plates 52 are connected through connecting plates 53, a filter screen 54 is fixedly arranged on one side, far away from the input pipeline 51, of the dehumidification plates 52, a temperature return cavity 55 is arranged on one side, far away from the filter screen 54, of the drying filter box 50, a heating pipe 56 is arranged in the temperature return cavity 55, a fan base 57 is arranged on one side, far away from the filter screen 54, of the temperature return cavity 55, a fan rotating shaft 58 is connected to the middle part in the fan base 57 in a sliding mode, and a fan 59 is arranged outside the fan rotating shaft 58.

Further, a cylinder is fixed on one side of the drying and filtering box 50 far away from the fan base 57, a drying particle plate 60 is arranged on one side of the cylinder, a purifying plate 61 is arranged on one side of the drying particle plate 60, an air outlet hole 62 is arranged in the cylinder, a collecting box 65 is fixed on one end of the cylinder, a spiral air cooling plate 63 is arranged between the outside of the collecting box 65 and the drying and filtering box 50, and an air inlet 64 is fixed on one end of the drying and filtering box 50.

Principle of operation

When the magnetic connection block 48 is powered off, the suction force between the magnetic connection block 48 and the cover plate 14 disappears, the cover plate 14 is opened, the cover plate shaft 13 and the cover plate connection shaft 12 slide relatively by rotating the cover plate 14, and meanwhile, the angle between the box horizontal rail 15 and the cover plate horizontal rail 16 is gradually reduced from vertical until the box horizontal rail 15 and the cover plate horizontal rail 16 are positioned at the same level, the rails are communicated, the sliding block 22 slides from the box horizontal rail 15 to the cover plate horizontal rail 16 to enter the outside, and the sealing connection film 26 can seal and connect the box horizontal rail 15 and the cover plate horizontal rail 16.

When the sliding block 22 moves outwards, the shock-absorbing inner box 27 is driven to move outwards, the shock-absorbing inner box 27 moves outwards to enable the sealing sliding plate 46 to be disconnected with the shock-absorbing inner box 27, meanwhile, the moving plates 44 start to slide, the moving plates 44 start to compress, when the moving plates 44 rotate relatively, the angle between the moving plates 44 is reduced, one ends of the moving plates 44 stretch into teeth of the limiting plate 41, the angle between the moving plates 44 is continuously reduced, the distance between the moving plates 44 and the gear 41 is reduced until the moving plates 44 abut against the gear 41 and drive the gear 41 to rotate, the gear 41 rotates to drive the rotating shaft 39 to rotate the belt pulley 40, the belt 42 rolls back, the rotating wheel 34 is pulled to start to slide upwards in the limiting groove 37, meanwhile, the connecting rod in the moving groove 36 slides upwards to enable the placing platform 31 to start to ascend horizontally, meanwhile, the auxiliary telescopic rod 30 in the auxiliary telescopic shell 29 ascends synchronously, the horizontal stability of the placing platform 31 is kept to lift the rare earth placing box 32, the position of the limiting plate 35 is stopped, the rare earth catalytic material is conveniently taken out, the sealing film 47 can help the inside the constant-temperature inner box 27 to keep the temperature inside the shock-absorbing box 27 to keep the two sides of the limiting block 32 to slide, and the limit block 33 can be prevented from sliding.

After the rare earth catalytic material is packaged, the damping inner box body 27 is pushed into the box body 10 until the sliding block 22 contacts with the horizontal buffer block 20, the horizontal buffer block 20 can limit the sliding block 22 and buffer the impact of the sliding block 22, when the sliding block 22 impacts the horizontal buffer block 20, the horizontal telescopic rod 19 moves into the horizontal telescopic shell 18, meanwhile, the first spring 21 compresses, the impact force of the sliding block 22 is pushed back, the force generated by sliding of the sliding block 22 is buffered, when the cover plate 14 rotates to be connected and closed with the magnetic connection block 48, the sliding block 22 and the horizontal buffer block 20 are in a close contact state, meanwhile, a certain extrusion force is provided for the first spring 21, and the sliding block 22 is prevented from moving in the horizontal track 15 of the box body when the box body 10 moves, so that the rare earth placing box 32 is prevented from vibrating.

The shock-absorbing telescopic rod 24 cooperates with the shock-absorbing telescopic shell 23 and the buffer spring 25 to absorb shock of the shock-absorbing inner box 27 when the box 10 vibrates up and down, and supports the shock-absorbing inner box 27 through the counter thrust of the buffer spring 25 and neutralizes the force generated by the up-and-down vibration of the shock-absorbing inner box 27.

The drying and filtering box 50 can dry the gas in the box 10 and filter external impurities, air in the protection box is dried, rare earth is prevented from being polluted and deteriorated, when the fan 59 rotates to drive the external air to enter the drying and filtering box 50 and pass through the dehumidifying plate 52, moisture of the external air is liquefied on the dehumidifying plate 52, the dried gas enters the temperature return cavity 55 through the filter screen 54 and is heated by the heating pipe 56 to be warmed up, the dried gas enters the collecting box 65 through the fan 59, the redundant impurities in the air and the gas polluted by rare earth are purified through the combined action of the drying and granulating plate 60 and the purifying plate 61, finally the gas flows to the spiral cold air plate 63 through the air outlet hole 62, the gas is cooled through the spiral cold air plate 63, and finally the air inlet 64 is output to the box 10.

The foregoing description is only illustrative of the present invention and is not intended to limit the scope of the invention, and all equivalent structures or equivalent processes using the descriptions and the drawings of the present invention or directly or indirectly applied to other related technical fields are included in the scope of the invention.

Claims (3)

1. The utility model provides a rare earth catalytic material stores transport case, includes box (10), its characterized in that, box (10) bottom one side is equipped with apron spread groove (11), apron spread groove (11) interior both sides symmetry has set firmly apron connecting axle (12), the one end sliding connection of apron connecting axle (12) has apron axle (13), one side of apron axle (13) has set firmly apron (14), box (10) bottom is equipped with a plurality of box horizontal track (15) along box (10) width direction symmetry, be equipped with a plurality of apron horizontal track (16) along apron (14) length direction symmetry on apron (14), apron horizontal track (16) can be linked together with box horizontal track (15) under certain state, one side and box (10) junction has set firmly horizontal shock absorber base (17) in box horizontal track (15), horizontal shock absorber base (17) are last to have set firmly horizontal telescopic housing (18), horizontal telescopic housing (18) are equipped with horizontal pole (19) in the inner slide, horizontal pole (19) have a plurality of apron horizontal track (16) along apron (14) length direction symmetry, horizontal pole (19) have a horizontal shock absorber block (20) to be connected with a horizontal spring (20), a plurality of sliding blocks (22) are arranged in the box body horizontal track (15) in a sliding manner; the device is characterized in that a cushioning telescopic shell (23) is symmetrically and fixedly arranged on two sides of the sliding block (22), a cushioning telescopic rod (24) is arranged in the cushioning telescopic shell (23) in a sliding mode, a buffer spring (25) is arranged in the middle of the upper end of the sliding block (22), the other end of the buffer spring (25) is connected with a damping inner box body (27), the outer surface of a box body horizontal rail (15) and the outer surface of a cover plate horizontal rail (16) are in sealing connection through a sealing connection film (26), a plurality of auxiliary telescopic bases (28) are fixedly arranged on the inner bottom of the damping inner box body (27), an auxiliary telescopic shell (29) is fixedly arranged on the auxiliary telescopic base (28), an auxiliary telescopic rod (30) is arranged in the auxiliary telescopic shell (29) in a sliding mode, a placing platform (31) is fixedly arranged at the output end of the auxiliary telescopic rod (30), sliding connecting rods are arranged at the end parts of two sides of the placing platform (31), a rare earth placing box (32) are fixedly arranged in the middle of the upper end of the placing platform (31), and a limiting block (33) is fixedly arranged outside the rare earth placing box (32); one side of the two inner side walls of the shock absorption inner box body (27) is provided with a moving groove (36), one side of the two side sliding connecting rods at one end of the placing platform (31) slides in the moving groove (36), one side of the moving groove (36) is provided with a limiting groove (37), the other side of the two side sliding connecting rods of the placing platform (31) is provided with a rotating wheel (34) in a sliding manner, the rotating wheel (34) slides in the limiting groove (37), one side of the bottom of the shock absorption inner box body (27) is fixedly provided with a supporting rod (38), one end of the supporting rod (38) is fixedly connected with a rotating shaft (39), a belt pulley (40) is fixedly arranged outside the rotating shaft (39), one side of the rotating shaft (39) is fixedly provided with a gear (41), a belt (42) is arranged outside the belt pulley (40), and the upper end of the rotating wheel (34) on the inner side wall of the shock absorption inner box body (27) is fixedly provided with a fixing rod (43). The shock attenuation is interior top one side slip is equipped with movable plate (44) in box (27), the one end slip of movable plate (44) is equipped with connecting axle (45), connecting axle (45) outer sliding connection has movable plate (44), and is repeated in proper order, connecting axle (45) sliding connection on movable plate (44) terminal has sealed sliding plate (46), sealed sliding plate (46) are last to have set firmly magnetism and inhale connecting block (48), sealed membrane (47) have been set firmly with movable plate (44) homonymy top in shock attenuation interior box (27), the other end and the sealed sliding plate (46) of sealed membrane (47) link to each other, magnetism is inhaled connecting block (48) and is set firmly in box (10) lower extreme one side recess.

2. A rare earth catalytic material storage and transportation tank as claimed in claim 1, wherein: the drying and ventilating box comprises a box body (10), a drying and ventilating cavity (49) is formed in one side of the box body (10), a drying and ventilating box (50) is arranged in the drying and ventilating cavity (49), an input pipeline (51) is fixedly arranged on one side of the drying and ventilating box (50), one end of the input pipeline (51) is communicated with the outside of the box body (10), a plurality of dehumidification boards (52) are arranged on one side, close to the input pipeline (51), of the drying and ventilating box (50) in the width direction of the drying and ventilating box (50), the dehumidification boards (52) are connected through a connecting plate (53), a filter screen (54) is fixedly arranged on one side, far away from the input pipeline (51), of the dehumidification boards (52), a temperature return cavity (55) is arranged on one side, far away from the filter screen (54), of the temperature return cavity (55) is provided with a fan base (57), a fan rotating shaft (58) is connected to the middle part in the fan base (57) in a sliding mode, and a fan rotating shaft (59) is arranged outside the fan rotating shaft (58).

3. A rare earth catalytic material storage and transportation tank as claimed in claim 2, wherein: one side of keeping away from fan base (57) in drying filter box (50) has set firmly the drum, one side is equipped with dry particle board (60) in the drum, one side of dry particle board (60) is equipped with purification board (61), be equipped with air outlet (62) in the drum, collecting box (65) have set firmly in the one end of drum, collecting box (65) are outer and drying filter box (50) space department is equipped with spiral cold air board (63), air intake (64) have set firmly in the one end of drying filter box (50).