CN218097099U - Scale graphite high temperature drying device - Google Patents

Abstract

The utility model relates to a graphite processing field especially relates to a scale graphite high temperature drying device, the utility model discloses a when solving prior art's scale graphite and drying, because pile up the motion grinding each other between graphite, cause the technical problem of the loss of big scale graphite, the range upon range of heat-resisting belt transmission that is equipped with in the drying chamber, vertical adjacent heat-resisting belt transmission skew is crisscross arranges, skew length is less than heat-resisting belt transmission transport length 1/4, the heat-resisting belt transmission links to each other with power, the feed inlet, the discharge gate is located two walls at the bottom of the drying chamber top respectively, upper portion heat-resisting belt transmission top is equipped with the feed inlet, lower extreme heat-resisting belt transmission lower part is equipped with the discharge gate, the heat-resisting belt transmission makes graphite can not pile up, the crisscross heat-resisting belt who arranges of skew has prolonged the stoving stroke and has made graphite turn-over, the thermally equivalent, can not reduce the temperature because of arranging when arranging the tide mouth messenger graphite and carrying the stoving, it dials the board to set up the stereoplasm and has reduced the graphite height, prevent that the graphite from breaking, and realize the whole heat-resisting belt transmission of a power synchro-control.

Description

Scale graphite high temperature drying device

Technical Field

The utility model relates to a graphite processing field especially relates to a scale graphite high temperature drying device.

Background

The crystalline flake graphite is natural crystalline graphite which is similar to fish phosphorus in shape, belongs to a hexagonal system, is in a layered structure, has good performances of high temperature resistance, lubrication, plasticity, acid and alkali resistance and the like, and is widely used due to low price as a natural lubricant;

when prior art's scale graphite was dried, because the motion grinding that piles up each other between the graphite causes the loss of big scale graphite, the utility model provides an above-mentioned problem.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a when solving prior art's scale graphite and drying, because pile up the motion grinding each other between the graphite, cause the technical problem of big scale graphite's loss, and then provide a scale graphite high temperature drying device.

An flake graphite high-temperature drying device, comprising: the hot air mechanism can drive hot air to the inside of the drying chamber, heat-resistant belt transmission is arranged in the drying chamber in a stacked mode, vertical adjacent heat-resistant belt transmission is arranged in a staggered mode in an offset mode, the offset length is smaller than 1/4 of the conveying length of the heat-resistant belt transmission, the heat-resistant belt transmission is connected with power, a feed inlet and a discharge port are respectively located in the top and bottom two walls of the drying chamber, the feed inlet is arranged above the uppermost heat-resistant belt transmission, and the discharge port is arranged at the lower portion of the lowermost heat-resistant belt transmission.

Furthermore, a moisture discharge port is arranged at the transmission offset gap of the adjacent heat-resistant belts and communicated with an air pump.

Furthermore, hot-blast mechanism includes the air heater, and the air heater is linked together with the hot-blast main, and the hot-blast main is linked together through air intake, roof air intake and drying chamber, and the air intake is located between two belts of heat-resisting belt transmission, and the roof air intake is located the drying chamber roof, is equipped with the fine hole on the driven belt of heat-resisting belt.

Furthermore, the heat-resistant belt transmission comprises power, the power is connected to the outer wall of the drying chamber, the power output end is connected with the shaft end of the conveying roller, the shaft end of the conveying roller is rotatably connected to the drying chamber, every two conveying rollers are connected through the heat-resistant belt, the heat-resistant belt is provided with hard shifting plates, and the upper hard shifting plate and the lower hard shifting plate are arranged in an overlapped and staggered mode.

Further, the hard shifting plate is connected with the heat-resistant belt, and the bottom of the hard shifting plate is thickened.

The utility model discloses beneficial effect:

1. the graphite is conveyed statically and cannot be stacked through the transmission of the heat-resistant belts, the drying stroke is prolonged through the heat-resistant belts arranged in an offset and staggered manner, and the graphite is turned over and uniformly heated;

2. the moisture discharging port is arranged at the offset gap, so that the temperature can not be reduced due to moisture discharging when the graphite is conveyed and dried;

3. the hard shifting plate is arranged, so that the graphite falling height is reduced, the graphite is prevented from being broken, and the transmission of all heat-resistant belts is synchronously controlled by one power.

Drawings

FIG. 1 is a first schematic structural diagram of the present invention;

FIG. 2 is a second schematic structural view of the present invention;

FIG. 3 is a schematic structural section of the present invention;

in the figure: a drying chamber 1; a hot air mechanism 2; a hot air mechanism 2; a hot air blower 21; a hot air duct 22; an air inlet 23; a feed port 3; a discharge port 4; a heat-resistant belt transmission 5; a power 51; a conveying roller 52; a heat-resistant belt 53; a hard dial plate 54; a moisture discharge port 6; and a suction pump 7.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts all belong to the protection scope of the present invention.

The rotary connection in the device means that the bearing is arranged on the shaft in a drying way, a spring retainer ring groove is arranged on the shaft or the shaft hole, and the elastic retainer ring is clamped in the retainer ring groove to realize the axial fixation of the bearing and realize the rotation; the hinge joint is a movable connection mode on connecting parts such as a hinge, a pin shaft, a short shaft and the like.

The present invention will be described in detail with reference to the accompanying drawings.

The first embodiment is as follows:

the high-temperature drying device for flake graphite in this embodiment is described below with reference to fig. 1 to 3, and includes: the hot air mechanism 2 can blow hot air into the drying chamber 1, heat-resistant belt drives 5 are stacked in the drying chamber 1, the vertically adjacent heat-resistant belt drives 5 are arranged in an offset staggered manner, the offset length is smaller than 1/4 of the conveying length of the heat-resistant belt drives 5, the heat-resistant belt drives 5 are connected with power, a feed port 3 and a discharge port 4 are respectively positioned on two walls of the top and the bottom of the drying chamber 1, the feed port 3 is arranged above the heat-resistant belt drive 5 on the uppermost part, and the discharge port 4 is arranged on the lower part of the heat-resistant belt drive 5 on the lowermost part;

pour into graphite into through feed inlet 3, graphite falls on heat-resisting belt drive 5, open hot-blast mechanism 2, hot-blast mechanism 2 bleeds hot-blast and dries graphite, heat-resisting belt drive 5 is static with graphite and carries to the end, graphite can not pile up the friction and smash, the crisscross arrangement of vertical adjacent heat-resisting belt drive 5 skew, graphite rolls and falls in below heat-resisting belt drive 5, accomplish the turn-over, each face graphite of being convenient for is dried, under the belt cushioning effect, the graphite impact has been weakened, prevent graphite destruction, and prolonged graphite stroke and stoving time, graphite moves to lower floor's heat-resisting belt drive 5 and discharges through discharge gate 4, accomplish and protect big scale graphite to dry.

A moisture discharge port 6 is arranged at the offset gap of the adjacent heat-resistant belt transmission 5, and the moisture discharge port 6 is communicated with an air pump 7; the air pump 7 finishes air pumping to exhaust moisture, and the moisture exhaust port 6 is arranged at the offset gap, so that the graphite is not cooled due to moisture exhaust when the central drying temperature of the heat-resistant belt transmission 5 is the highest;

the hot air mechanism 2 comprises a hot air blower 21, the hot air blower 21 is communicated with a hot air pipe 22, the hot air pipe 22 is communicated with the drying chamber 1 through an air inlet 23 and a top wall air inlet 24, the air inlet 23 is positioned between two heat-resistant belt transmission belts 5, the top wall air inlet 24 is positioned on the top wall of the drying chamber 1, and a belt of the heat-resistant belt transmission belts 5 is provided with fine holes;

hot air from the hot air blower 21 enters the drying chamber 1 through the hot air pipe 22, the air inlet 23 and the top wall air inlet 24, the uppermost layer of graphite is dried by the top wall air inlet 24 through hot air, the hot air at the position of the air inlet 23 is diffused up and down after entering the drying chamber 1, the graphite permeates between the graphite layers on the heat-resistant belt transmission 5 through the fine holes in the belt, the fine holes are larger than the graphite particle size, the graphite cannot drop, the graphite is uniformly heated, and the drying is completed.

The heat-resistant belt transmission 5 comprises power 51, the power 51 is connected to the outer wall of the drying chamber 1, the output end of the power 51 is connected with the shaft end of a conveying roller 52, the shaft end of the conveying roller 52 is rotatably connected to the drying chamber 1, every two conveying rollers 52 are connected through a heat-resistant belt 53, a hard shifting plate 54 is arranged on the heat-resistant belt 53, and the upper hard shifting plate 54 and the lower hard shifting plate 54 are arranged in an overlapping and staggered mode;

power 51 drives conveying roller 52 and rotates, two conveying rollers 52 drive the heat-resisting band 53 operation, on, the crisscross setting of board 54 overlap is dialled to lower stereoplasm, board 54 drives adjacent heat-resisting band 53 operation is dialled through the stereoplasm to the heat-resisting band 53, start stopping simultaneously through single power makes all heat-resisting bands 53 like this, it can not disintegrate because of the differential to eliminate speed difference between the heat-resisting band 53 when guaranteeing that graphite falls, through on, the board 54 overlaps and forms individual space down is dialled to lower stereoplasm, the temperature is higher in the space, drying effect is better, it just can fall to the graphite after the lower part is rotated to the board 54 to dial to the stereoplasm, the height that the graphite falls has been reduced, prevent that graphite from breaking into pieces.

The hard shifting plate 54 is connected with the heat-resistant belt 53, and the bottom of the hard shifting plate is thickened;

the hard shifting plate 54 is connected with the heat-resistant belt 53, the bottom is thickened, so that the bottom is stable and the corner is small when the hard shifting plate 54 is shifted, and the hard shifting plate 54 cannot be broken or elastically bent by 90 degrees.

It should be noted that, in this document, relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrases "comprising one of 8230; \8230;" 8230; "does not exclude the presence of additional like elements in a process, method, article, or apparatus that comprises the element.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that various changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. An flake graphite high-temperature drying device, comprising: a drying chamber (1), a hot air mechanism (2), wherein the hot air mechanism (2) can blow hot air into the drying chamber (1),

the method is characterized in that: drying chamber (1) inlayer is folded and is equipped with heat-resisting belt drive (5), and vertical adjacent heat-resisting belt drive (5) skew is crisscross arranges, and skew length is less than heat-resisting belt drive (5) transport length 1/4, and heat-resisting belt drive (5) link to each other with power, and feed inlet (3), discharge gate (4) are located drying chamber (1) two walls at the bottom of the top respectively, and uppermost heat-resisting belt drive (5) top is equipped with feed inlet (3), and lowermost heat-resisting belt drive (5) lower part is equipped with discharge gate (4).

2. The flake graphite high-temperature drying device according to claim 1, wherein: and a moisture discharge port (6) is arranged at the offset gap of the adjacent heat-resistant belt transmission (5), and the moisture discharge port (6) is communicated with an air pump (7).

3. The flake graphite high-temperature drying device according to claim 1, wherein: the hot air mechanism (2) comprises a hot air blower (21), the hot air blower (21) is communicated with a hot air pipe (22), the hot air pipe (22) is communicated with the drying chamber (1) through an air inlet (23) and a top wall air inlet (24), the air inlet (23) is located between two heat-resistant belt transmission belts (5), the top wall air inlet (24) is located on the top wall of the drying chamber (1), and fine and dense holes are formed in a belt of the heat-resistant belt transmission belts (5).

4. The flake graphite high-temperature drying device according to claim 1, wherein: the heat-resistant belt transmission (5) comprises power (51), the power (51) is connected to the outer wall of the drying chamber (1), the output end of the power (51) is connected with the shaft ends of the conveying rollers (52), the shaft ends of the conveying rollers (52) are rotatably connected to the drying chamber (1), every two conveying rollers (52) are connected through a heat-resistant belt (53), hard poking plates (54) are arranged on the heat-resistant belt (53), and the upper hard poking plates (54) and the lower hard poking plates (54) are arranged in an overlapped and staggered mode.

5. The flake graphite high-temperature drying device according to claim 4, wherein: the hard shifting plate (54) is connected with the heat-resistant belt (53), and the bottom of the hard shifting plate is thickened.

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