CN113479883B - Automatic charcoal equipment of receiving of active carbon semi-manufactured goods - Google Patents

Abstract

The invention relates to the technical field of activated carbon production, and discloses automatic activated carbon semi-finished product carbon collecting equipment which comprises a carbon collecting box, wherein the upper end of the carbon collecting box is provided with a feeding channel communicated with the carbon collecting box, the upper end of the feeding channel is provided with a carbonization furnace connecting part, the carbonization furnace connecting part is provided with a carbon drawing mechanism, and the bottom of the carbon collecting box is provided with a carbon outlet mechanism. The automatic carbonization device can automatically transfer the semi-finished activated carbon in the carbonization furnace into the carbon collection box, can effectively improve the efficiency of taking the activated carbon, can effectively solve the problems of scalding and the like of workers, and improves the working safety of workers.

Description

Automatic charcoal equipment of receiving of active carbon semi-manufactured goods

Technical field:

the invention relates to the technical field of activated carbon production, in particular to automatic activated carbon semi-finished product collecting equipment.

The background technology is as follows:

when the activated carbon is prepared from the straws, the straws are firstly cut up, then the crushed straws are put into a carbonization furnace for carbonization, and the carbonized activated carbon semi-finished product is transferred into an activated carbon activation furnace for activation; because the carbonized active carbon semi-finished product and the carbonization furnace have higher temperature, the active carbon semi-finished product is easy to scald when being manually taken out from the carbonization furnace, and potential safety hazards exist; meanwhile, the efficiency of manually taking the carbon is low, so that the production efficiency of the activated carbon is influenced.

The invention comprises the following steps:

the invention aims to overcome the defects of the prior art and provides automatic activated carbon semi-finished product collecting equipment, which can automatically transfer the activated carbon semi-finished product in a carbonization furnace into a carbon collecting box, can effectively improve the activated carbon material taking efficiency, can effectively solve the problems of scalding and the like of workers, and improves the working safety of the workers.

The scheme for solving the technical problems is as follows: the utility model provides an automatic charcoal equipment of receiving of active carbon semi-manufactured goods, includes receives the charcoal case, the upper end of receiving the charcoal case is equipped with rather than communicating feed channel, and feed channel's upper end is equipped with retort connecting portion, is equipped with on the retort connecting portion and draws charcoal mechanism, the bottom of receiving the charcoal case is equipped with out charcoal mechanism.

A feed inlet is formed at the left end of the carbon collection box, and the lower end of the feed channel is fixedly connected with the feed inlet; a row of first dust plates and a row of second dust plates which are obliquely arranged downwards are fixed on the inner wall of the feeding channel, and the row of first dust plates and the row of second dust plates are staggered left and right;

the bottom of the feeding channel is fixedly provided with a third dust baffle which is obliquely arranged downwards, and the right end of the third dust baffle extends into the lower part of the right end of the feeding hole.

The connecting part of the carbonization furnace comprises a connecting base part fixed at the upper end of the feeding channel, a sleeve ring and a positioning boss, which are coaxially arranged and bulge leftwards, are formed on the connecting base part, the sleeve ring is inserted and sleeved on the outer wall of the open end of the furnace body of the carbonization furnace, a positioning sleeve is arranged in the middle of the furnace body, and the positioning boss is inserted and sleeved in the positioning sleeve;

the semi-finished product of the activated carbon is arranged in a cavity formed by the inner wall of the furnace body and the outer wall of the positioning sleeve;

the lower end of the connecting base is provided with a transition channel which is communicated with the inner space of the lantern ring and the feeding channel.

The lower bottom surface of the transition channel is obliquely arranged at left, right and left sides.

A counter bore with an opening at the left side is formed on the positioning boss, and two waist-shaped long holes which are arranged front and back are formed on the lower side wall of the counter bore;

the carbon drawing mechanism comprises a sliding block which is in sliding connection in the counter bore, the middle part of the sliding block is in threaded connection with a screw rod arranged in the left-right direction, the left end of the screw rod is hinged on a connecting ring through a bearing, the connecting ring is fixed at the left end of the counter bore, the screw rod penetrates through the right extending end of the connecting base part to be fixedly connected with a motor shaft of a first motor, and the first motor is fixed on the connecting base part through a motor bracket; two L-shaped push-pull rods which are arranged front and back are fixed on the sliding block, and carbon drawing plates are fixed at the ends of the two L-shaped push-pull rods, which penetrate through the corresponding waist-shaped long holes.

The lower end of the carbon drawing plate is provided with an arc bottom surface matched with the inner wall of the lower end of the furnace body, and a chamfer part is formed above the left end of the carbon drawing plate;

the upper end of the sliding block is provided with an arc-shaped part matched with the inner wall of the upper end of the counter bore, and the arc-shaped part is pressed against the inner wall of the counter bore.

A carbonization furnace vibration supply mechanism is arranged in the counter bore; a platform is formed on the inner wall of the lower side of the counter bore, and a plurality of guide limiting holes penetrating up and down are formed on the platform;

the carbonization furnace vibration supply mechanism comprises a second motor, wherein a plurality of upper guide limit rods and lower guide limit rods are respectively fixed on the upper bottom surface and the lower bottom surface of the second motor, each lower guide limit rod is inserted and sleeved in a corresponding guide limit hole, each upper guide limit rod is inserted and sleeved in a guide through hole of a corresponding support arranged in a Z shape, a plurality of disc springs are respectively sleeved on the upper guide limit rods and the lower guide limit rods, the plurality of disc springs sleeved on the upper guide limit rods are clamped between the support and the upper bottom surface of the second motor, and the plurality of disc springs sleeved on the lower guide limit rods are clamped between a platform and the lower bottom surface of the second motor; the support is fixed on the platform, and a cam is fixed at the left extending end of the motor shaft of the second motor extending to the counter bore.

When the second motor does not work, the convex end of the cam is just contacted with the inner wall of the lower end of the positioning sleeve when facing downwards.

A carbon dropping hole and a discharging channel which is arranged in the left-right direction and is communicated with the carbon dropping hole and is provided with a right opening are formed on the lower bottom surface of the carbon collecting box;

the carbon outlet mechanism comprises a spiral conveying shaft inserted in the discharging channel, a supporting shaft arranged coaxially is fixed at the left end of the spiral conveying shaft, the supporting shaft is hinged at the left end of the discharging channel through a bearing, the left end of the supporting shaft is fixedly connected with a motor shaft of a third motor, and the third motor is fixed at the bottom of the carbon collecting box; a shaft seal is sleeved on the support shaft, and the outer wall of the shaft seal is pressed against the inner wall of the discharging channel, which is positioned on the left side of the carbon dropping hole;

the carbon dropping hole is arranged at the lowest end of the lower bottom surface of the carbon collection box;

the right end of the discharging channel is connected with a detachable plug.

The bottom of the carbon collection box is provided with a plurality of rollers.

The invention has the outstanding effects that:

compared with the prior art, the automatic carbonization device can automatically transfer the semi-finished active carbon in the carbonization furnace into the carbon collection box, can effectively improve the active carbon material taking efficiency, can effectively solve the problems of scalding and the like of workers, and improves the working safety of workers.

Description of the drawings:

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

FIG. 2 is a left side view of the present invention;

FIG. 3 is an enlarged view of a portion of FIG. 1 about A;

FIG. 4 is a cross-sectional view of FIG. 3 taken about B-B;

FIG. 5 is a cross-sectional view of FIG. 3 about C-C;

FIG. 6 is a cross-sectional view of FIG. 5 taken about D-D;

fig. 7 is a partial enlarged view of fig. 1 with respect to E.

The specific embodiment is as follows:

the embodiment is shown in fig. 1 to 7, and the automatic activated carbon semi-finished product collecting device comprises a carbon collecting box 1, wherein a feeding channel 2 communicated with the carbon collecting box 1 is arranged at the upper end of the carbon collecting box 1, a carbonization furnace connecting part 3 is arranged at the upper end of the feeding channel 2, a carbon picking mechanism 4 is arranged on the carbonization furnace connecting part 3, and a carbon discharging mechanism 5 is arranged at the bottom of the carbon collecting box 1.

Further, a feed inlet 11 is formed at the left end of the carbon collection box 1, and the lower end of the feed channel 2 is fixedly connected with the feed inlet 11; a row of first dust plates 21 and a row of second dust plates 22 which are obliquely arranged downwards are fixed on the inner wall of the feeding channel 2, and the row of first dust plates 21 and the row of second dust plates 22 are arranged in a left-right staggered manner;

the bottom of the feeding channel 2 is fixedly provided with a third dust baffle 23 which is obliquely arranged downwards, and the right end of the third dust baffle 23 extends into the lower part of the right end of the feeding hole 11.

Furthermore, the connecting part 3 of the carbonization furnace comprises a connecting base part 31 fixed at the upper end of the feeding channel 2, a sleeve ring 32 and a positioning boss 33 which are coaxially arranged and protruded leftwards are formed on the connecting base part 31, the sleeve ring 32 is inserted and sleeved on the outer wall of the opening end of a furnace body 91 of the carbonization furnace 9, a positioning sleeve 92 is arranged in the middle of the furnace body 91, and the positioning boss 33 is inserted and sleeved in the positioning sleeve 92;

the semi-finished product of the activated carbon is placed in a cavity formed by the inner wall of the furnace body 91 and the outer wall of the positioning sleeve 92;

the lower end of the connection base 31 is formed with a transition passage 34 communicating the inner space of the collar 32 with the feed passage 2.

Further, the lower bottom surface of the transition channel 34 is inclined to be higher and lower.

Further, the positioning boss 33 is formed with a counter bore 35 with a left opening, and the lower side wall of the counter bore 35 is formed with two waist-shaped long holes 36 arranged front and back;

the carbon drawing mechanism 4 comprises a sliding block 41 which is slidably connected in the counter bore 35, the middle part of the sliding block 41 is in threaded connection with a screw rod 42 which is arranged in the left-right direction, the left end of the screw rod 42 is hinged on a connecting ring 43 through a bearing, the connecting ring 43 is fixed at the left end of the counter bore 35, the screw rod 42 penetrates through the right extending end of the connecting base 31 to be fixedly connected with a motor shaft of a first motor 44, and the first motor 44 is fixed on the connecting base 31 through a motor bracket 45; two L-shaped push-pull rods 46 arranged front and back are fixed on the sliding block 41, and carbon drawing plates 47 are fixed at the ends of the two L-shaped push-pull rods 46 penetrating through the corresponding waist-shaped long holes 36.

Further, the lower end of the carbon drawing plate 47 is formed with an arc bottom surface 471 matched with the inner wall of the lower end of the furnace body 91, and the upper part of the left end of the carbon drawing plate 47 is formed with a chamfer 472;

the upper end of the slider 41 is formed with an arc-shaped portion 411 matching with the inner wall of the upper end of the counter bore 35, and the arc-shaped portion 411 is pressed against the inner wall of the counter bore 35.

Further, a carbonization furnace vibration supply mechanism 6 is arranged in the counter bore 35; a platform 37 is formed on the inner wall of the lower side of the counter bore 35, and a plurality of guide limiting holes 38 penetrating up and down are formed on the platform 37;

the carbonization furnace vibration supply mechanism 6 comprises a second motor 61, wherein a plurality of upper guide limit rods 62 and lower guide limit rods 63 are respectively fixed on the upper bottom surface and the lower bottom surface of the second motor 61, each lower guide limit rod 63 is inserted and sleeved in a corresponding guide limit hole 38, each upper guide limit rod 62 is inserted and sleeved in a guide through hole 641 of a corresponding Z-shaped support 64, a plurality of disc springs 65 are respectively sleeved on the upper guide limit rods 62 and the lower guide limit rods 63, the plurality of disc springs 65 sleeved on the upper guide limit rods 62 are clamped between the support 64 and the upper bottom surface of the second motor 61, and the plurality of disc springs 65 sleeved on the lower guide limit rods 63 are clamped between the platform 37 and the lower bottom surface of the second motor 61; the support 64 is fixed on the platform 37, and a cam 66 is fixed at the left protruding end of the motor shaft of the second motor 61 protruding to the counter bore 35.

Further, when the second motor 61 is not operated, the convex end of the cam 66 is just contacted with the inner wall of the lower end of the positioning sleeve 92 when facing downwards.

Further, a carbon dropping hole 12 and a discharging channel 13 which is arranged in the left-right direction and is communicated with the carbon dropping hole 12 and is provided with a right opening are formed on the lower bottom surface of the carbon collecting box 1;

the carbon outlet mechanism 5 comprises a spiral conveying shaft 51 inserted in the discharge channel 13, a supporting shaft 52 arranged coaxially is fixed at the left end of the spiral conveying shaft 51, the supporting shaft 52 is hinged at the left end of the discharge channel 13 through a bearing, the left end of the supporting shaft 52 is fixedly connected with a motor shaft of a third motor 53, and the third motor 53 is fixed at the bottom of the carbon collecting box 1; the support shaft 52 is also sleeved with a shaft seal 54, and the outer wall of the shaft seal 54 is pressed against the inner wall of the discharging channel 13, which is positioned on the left side of the carbon falling hole 12;

the carbon dropping hole 12 is arranged at the lowest end of the lower bottom surface of the carbon collection box 1;

the right end of the discharging channel 13 is connected with a detachable plug 55.

Further, a plurality of rollers 7 are arranged at the bottom of the carbon collection box 1.

Working principle: firstly, the device can be easily moved to the corresponding carbonization furnace 9 through the roller 7, the positioning boss 33 is aligned with the positioning sleeve 92 of the carbonization furnace 9 and is inserted into the positioning sleeve 92, the furnace body 91 of the carbonization furnace 9 is inserted into the lantern ring 32, and when the end part of the furnace body 91 of the carbonization furnace is pressed against the end surface of the connecting base 31, the device stops moving;

secondly, the first motor 44 drives the screw rod 42 to rotate, the screw rod 42 drives the sliding block 41 to move leftwards, and the sliding block 41 drives the carbon drawing plate 47 to move leftwards through the L-shaped push-pull rod 46 and is inserted into the furnace body 91; when the first motor 44 rotates forward for a certain number of turns, the first motor 44 rotates reversely for the same number of turns, and the carbon drawing plate 47 moves back and forth by the switching of the forward rotation and reverse rotation of the first motor in a circulating manner; when the carbon drawing plate 47 moves leftwards, the chamfer 472 facilitates turning of the semi-finished product of the activated carbon on the left side of the carbon drawing plate 47 to the right side of the carbon drawing plate 47, and when the carbon drawing plate 47 moves rightwards, the semi-finished product on the right side of the carbon drawing plate 47 is pushed rightwards and pushed into the transition channel 34, and the semi-finished product of the activated carbon is conveniently arranged obliquely through the lower bottom surface of the transition channel 34 to enter the feeding channel 2;

the first motor 44 works and the second motor 61 drives the cam 66 to rotate, and the cam 66 continuously hits the inner wall of the positioning sleeve 92 under the action of centrifugal force, so that the positioning sleeve 92 is driven to vibrate, and the semi-finished activated carbon product at the upper side in the furnace body is convenient to slide downwards; the cam 66 reacts with the second motor 61 to move the second motor 61 upwards when contacting and separating from the positioning sleeve 92, and then moves downwards under the action of the disc spring to automatically reset; the second motor 61 moves up and down to generate slight vibration and act on the connecting part 3 of the carbonization furnace to accelerate the semi-finished product of the activated carbon in the transition channel 34 to enter the feeding channel 2;

thirdly, the semi-finished activated carbon in the transition channel 34 slides down to the third dust plate 23 along the first dust plate 21 and the second dust plate 22 in sequence, and finally slides down to the carbon collection box 1; the first, second and third dust-blocking plates 21, 22 and 23 can effectively block the generated dust from overflowing outwards;

fourth, when the semi-finished product of the activated carbon in the carbon collection box 1 needs to be output outwards, the plug 55 is firstly taken down, then the third motor 53 drives the spiral conveying shaft 51 to rotate through the supporting shaft 52, the semi-finished product of the activated carbon in the carbon collection box 1 falls into the discharging channel 13 through the carbon falling hole 12, and then the semi-finished product of the activated carbon is conveyed to the outside of the right belt through the spiral conveying shaft 51.

Finally, the above embodiments are only for illustrating the invention, not for limiting it, and various changes and modifications can be made by one skilled in the relevant art without departing from the spirit and scope of the invention, so that all equivalent technical solutions are also within the scope of the invention, which is defined by the claims.

Claims (4)

1. The utility model provides an automatic charcoal equipment of receiving of active carbon semi-manufactured goods, includes and receives charcoal case (1), its characterized in that: the upper end of the carbon collection box (1) is provided with a feeding channel (2) communicated with the carbon collection box, the upper end of the feeding channel (2) is provided with a carbonization furnace connecting part (3), the carbonization furnace connecting part (3) is provided with a carbon drawing mechanism (4), and the bottom of the carbon collection box (1) is provided with a carbon outlet mechanism (5);

a feed inlet (11) is formed at the left end of the carbon collection box (1), and the lower end of the feed channel (2) is fixedly connected with the feed inlet (11); a row of first dust plates (21) and a row of second dust plates (22) which are obliquely arranged downwards are fixed on the inner wall of the feeding channel (2), and the row of first dust plates (21) and the row of second dust plates (22) are arranged in a left-right staggered manner;

a third dust plate (23) which is obliquely arranged downwards is fixed at the bottom of the feeding channel (2), and the right end of the third dust plate (23) extends into the lower part of the right end of the feeding hole (11);

the carbonization furnace connecting part (3) comprises a connecting base part (31) fixed at the upper end of the feeding channel (2), a left-protruding sleeve ring (32) and a positioning boss (33) which are coaxially arranged are formed on the connecting base part (31), the sleeve ring (32) is inserted and sleeved on the outer wall of the opening end of a furnace body (91) of the carbonization furnace (9), a positioning sleeve (92) is arranged in the middle of the furnace body (91), and the positioning boss (33) is inserted and sleeved in the positioning sleeve (92);

the semi-finished product of the activated carbon is arranged in a cavity formed by the inner wall of the furnace body (91) and the outer wall of the positioning sleeve (92);

the lower end of the connecting base part (31) is provided with a transition channel (34) which is used for communicating the inner space of the lantern ring (32) with the feeding channel (2);

the lower bottom surface of the transition channel (34) is obliquely arranged in a left-high right-low manner;

a counter bore (35) with an opening at the left side is formed on the positioning boss (33), and two waist-shaped long holes (36) which are arranged front and back are formed on the lower side wall of the counter bore (35);

the carbon drawing mechanism (4) comprises a sliding block (41) which is slidably connected in a counter bore (35), the middle part of the sliding block (41) is in threaded connection with a screw rod (42) arranged in the left-right direction, the left end of the screw rod (42) is hinged on a connecting ring (43) through a bearing, the connecting ring (43) is fixed at the left end of the counter bore (35), the screw rod (42) penetrates through the right extending end of a connecting base (31) to be fixedly connected with a motor shaft of a first motor (44), and the first motor (44) is fixed on the connecting base (31) through a motor bracket (45); two L-shaped push-pull rods (46) which are arranged front and back are fixed on the sliding block (41), and carbon drawing plates (47) are fixed at the ends of the two L-shaped push-pull rods (46) which penetrate through the corresponding waist-shaped long holes (36);

a carbonization furnace vibration supply mechanism (6) is arranged in the counter bore (35); a platform (37) is formed on the inner wall of the lower side of the counter bore (35), and a plurality of guide limiting holes (38) penetrating up and down are formed on the platform (37);

the carbonization furnace vibration supply mechanism (6) comprises a second motor (61), wherein a plurality of upper guide limit rods (62) and lower guide limit rods (63) are respectively fixed on the upper bottom surface and the lower bottom surface of the second motor (61), each lower guide limit rod (63) is inserted and sleeved in a corresponding guide limit hole (38), each upper guide limit rod (62) is inserted and sleeved in a guide through hole (641) of a corresponding Z-shaped support (64), a plurality of disc springs (65) are respectively sleeved on each upper guide limit rod (62) and each lower guide limit rod (63), the plurality of disc springs (65) sleeved on the upper guide limit rods (62) are clamped between the support (64) and the upper bottom surface of the second motor (61), and the plurality of disc springs (65) sleeved on the lower guide limit rods (63) are clamped between the platform (37) and the lower bottom surface of the second motor (61); the support (64) is fixed on the platform (37), and a cam (66) is fixed at the left extending end of the motor shaft of the second motor (61) extending to the counter bore (35);

when the second motor (61) is not in operation, the convex end of the cam (66) is just contacted with the inner wall of the lower end of the positioning sleeve (92) when facing downwards.

2. An automatic activated carbon semi-finished product collecting device according to claim 1, characterized in that: an arc-shaped bottom surface (471) matched with the inner wall of the lower end of the furnace body (91) is formed at the lower end of the carbon drawing plate (47), and a chamfer angle part (472) is formed above the left end of the carbon drawing plate (47);

the upper end of the sliding block (41) is provided with an arc-shaped part (411) matched with the inner wall of the upper end of the counter bore (35), and the arc-shaped part (411) is pressed against the inner wall of the counter bore (35).

3. An automatic activated carbon semi-finished product collecting device according to claim 1, characterized in that: a carbon dropping hole (12) and a discharging channel (13) which is arranged in the left-right direction and is communicated with the carbon dropping hole (12) and is provided with a right opening are formed on the lower bottom surface of the carbon collecting box (1);

the carbon outlet mechanism (5) comprises a spiral conveying shaft (51) inserted in the discharge channel (13), a supporting shaft (52) arranged coaxially is fixed at the left end of the spiral conveying shaft (51), the supporting shaft (52) is hinged at the left end of the discharge channel (13) through a bearing, the left end of the supporting shaft (52) is fixedly connected with a motor shaft of a third motor (53), and the third motor (53) is fixed at the bottom of the carbon collecting box (1); a shaft seal (54) is sleeved on the support shaft (52), and the outer wall of the shaft seal (54) is pressed against the inner wall of the discharging channel (13) positioned on the left side of the carbon falling hole (12);

the carbon dropping hole (12) is arranged at the lowest end of the lower bottom surface of the carbon collecting box (1);

the right end of the discharging channel (13) is connected with a detachable plug (55).

4. An automatic activated carbon semi-finished product collecting device according to claim 1, characterized in that: the bottom of the carbon collection box (1) is provided with a plurality of rollers (7).