CN109269301A - A kind of automation cycle sintering device for sintering activity filtration core - Google Patents

Abstract

The invention discloses a kind of automation cycle sintering devices for sintering activity filtration core, including cabinet, the inside of cabinet is provided with heat dissipation cavity and high temperature chamber, the upper surface of high temperature chamber is equipped with electric heating pump, the top of heat dissipation cavity is equipped with feed hopper, the inner lower of feed hopper is equipped with material toggling block, the side wall of cabinet is equipped with headstock, heat dissipation cavity and the inner rotation of high temperature chamber are connected with first, second pierce tap, the lateral wall of belt is flexibly connected with the sliding axle of solenoid valve and inner sidewall is flexibly connected with runner, of the invention first, second pierce tap rotation direction is opposite, to which the second pierce tap can produce high temperature chamber with the molding die sintered, and it can be in inside of the meeting in heat dissipation cavity and the lower section natural cooling positioned at the first pierce tap, the molding die sintered in this way is in heat dissipation, by the molding to be sintered on the first pierce tap Mold preheating, so that thermal energy when heat dissipation adequately be utilized.

Description

A kind of automation cycle sintering device for sintering activity filtration core

Technical field

The present invention relates to sintering activity filtration core technical field, specially a kind of automation for sintering activity filtration core Cycle sintering device.

Background technique

Currently, common filter core is generally activated carbon adsorption filtering in the market, active carbon filter core is sintered with carbon dust , existing ordinary sinter activated carbon filter element device is usually a small-sized flow-line equipment, and sintered finished product needs certainly Heat that is so cooling, being distributed due to the import of ordinary sinter activated carbon filter element device and when exporting the both ends, in this way cooling for being placed on device Amount cannot be used adequately, and from the product to be sintered that import flows into high temperature chamber be fired since natural temperature, To increase energy consumption when firing, the cost of ablating work procedure is increased in this way, and in existing sintering activity filtration core work In sequence, molding die is all slowly to cause artificial waste since pierce tap rotates by being manually placed on pierce tap, Therefore we have proposed a kind of automation cycle sintering devices for sintering activity filtration core.

Summary of the invention

The purpose of the present invention is to provide a kind of automation cycle sintering devices for sintering activity filtration core, to solve The problems mentioned above in the background art.

To achieve the above object, the invention provides the following technical scheme: a kind of automation for sintering activity filtration core Cycle sintering device, including cabinet, the inside of the cabinet from left to right successively open heat dissipation cavity and high temperature chamber, the high temperature chamber Upper surface be equipped with electric heating pump, the top of the heat dissipation cavity is equipped with feed hopper, and the inner lower of the feed hopper is equipped with material toggling The side wall of block, the cabinet is equipped with headstock, and the inside of the headstock is provided with cavity；

The inside of the heat dissipation cavity and high temperature chamber is rotatablely connected there are two shaft, and the inside of the heat dissipation cavity passes through two Shaft is rotatably connected to the first pierce tap and the second pierce tap respectively, and the first pierce tap is located at the upside of the second pierce tap, institute The one end for stating the first pierce tap and the second pierce tap runs through the side wall of heat dissipation cavity and extends to the inside of high temperature chamber, and the company of rotation It connects in the shaft in the intracavitary portion of high temperature；

One end of two shafts inside heat dissipation cavity run through the side wall of heat dissipation cavity and extend to cavity inside and It is rotatably connected to first gear, two first gear engagement connections, the side wall of the headstock is equipped with motor, the motor Output shaft runs through the side wall of headstock and extends to the inside of cavity, is provided with dark chamber on the side wall of the cavity, the dark chamber Inside by spring slide is connected with sliding block, is fixedly connected with second gear on the side wall of the sliding block, and second gear with it is upper Connection is engaged in the first gear activity of side, is rotatably connected to guide wheel, the output shaft of the motor, second on the side wall of the cavity Belt, the lateral wall and electromagnetism of the belt between the second gear and guide wheel are rotatably connected on the central axis and guide wheel of gear The sliding axle of valve is flexibly connected, and the solenoid valve is located at the inside of cavity, the belt between the second gear and guide wheel it is interior Side wall is flexibly connected with runner, and the central axis of the runner runs through the side wall of cavity and extends to inside and and the material toggling of feed hopper Block is fixedly connected.

Preferably, multiple blowing areas are equipped on first pierce tap and the second pierce tap, and multiple blowing areas are uniform Arrangement.

Preferably, baffle is equipped between the heat dissipation cavity and high temperature chamber.

Preferably, the inside of the high temperature chamber and it is located at the side of the first pierce tap and is rotatably connected to buffer stopper, it is described slow The lateral wall for rushing block is equipped with multiple arcs plate, and the either end of the buffer stopper is fixedly connected with the 4th gear, the 4th tooth Wheel engages connection with third gear, and the third gear is fixedly connected in the shaft of the first pierce tap.

Preferably, around buffer stopper, circumferentially shape arranges multiple arc panels.

Preferably, the junction of the sliding axle of the solenoid valve and belt is equipped with wheel shaft.

Compared with prior art, the beneficial effects of the present invention are: can be put inside the feed hopper that the present invention is equipped with a large amount of Molding die to be fired driven when the blowing area in the first pierce tap overhead goes to the underface of feed hopper by motor The rotation of material toggling block, such molding die just fall in the blowing area on the first pierce tap from the outlet at bottom of feed hopper one by one, The process manually slowly put just is saved in this way, to save manpower；And when molding die is transferred to by the first pierce tap After high temperature chamber, the molding die on final first pierce tap can be fallen into the blowing area on the second pierce tap, due to first, second Pierce tap rotation direction can dissipate on the contrary, to which the second pierce tap can produce high temperature chamber with the molding die sintered The inside of hot chamber and the lower section natural cooling for being located at the first pierce tap, the molding die sintered in this way will be in heat dissipation Molding die preheating to be sintered on first pierce tap, so that thermal energy when heat dissipation adequately be utilized, and flows into high temperature The product to be sintered of chamber are heated in heat dissipation cavity, lessen energy consumption when firing in this way, to reduce sintering The cost of active carbon filter core process.

Detailed description of the invention

Fig. 1 is the structural diagram of the present invention；

Fig. 2 is the cross-sectional view at cabinet and headstock of the invention；

Fig. 3 is enlarged drawing at the A of Fig. 2 of the invention；

Fig. 4 is the structural schematic diagram at the first pierce tap and the second pierce tap of the invention；

Fig. 5 is enlarged drawing at the B of Fig. 4 of the invention；

Fig. 6 is the entirety sectional view of the device of the invention；

Fig. 7 is the cross-sectional view at second gear and sliding block of the invention；

Fig. 8 is the structural schematic diagram at the first pierce tap of the invention, buffer stopper and arc panel.

In figure: 1, cabinet, 2, headstock, 3, feed hopper, 4, electric heating pump, 5, high temperature chamber, 6, heat dissipation cavity, the 7, first steel wire Band, the 8, second pierce tap, 9, blowing area, 10, material toggling block, 11, runner, 12, cavity, 13, first gear, 14, guide wheel, 15, electricity Machine, 16, belt, 17, second gear, 18, solenoid valve, 19, dark chamber, 20, spring, 21, sliding block, 22, buffer stopper, 23, arc panel, 24, third gear, the 25, the 4th gear, 26, baffle, 27, molding die, 28, shaft.

Specific embodiment

Following will be combined with the drawings in the embodiments of the present invention, and technical solution in the embodiment of the present invention carries out clear, complete Site preparation description, it is clear that described embodiments are only a part of the embodiments of the present invention, instead of all the embodiments.It is based on Embodiment in the present invention, it is obtained by those of ordinary skill in the art without making creative efforts every other Embodiment shall fall within the protection scope of the present invention.

Fig. 1-8 is please referred to, the present invention provides a kind of technical solution: a kind of automation circulation for sintering activity filtration core Sintering equipment, including cabinet 1, the inside of the cabinet 1 from left to right successively open heat dissipation cavity 6 and high temperature chamber 5, the high temperature chamber 5 upper surface, which is equipped with electric heating pump 4, can be warmed to suitable temperature for high temperature chamber 5, to be sintered work when electric heating pump 4 starts Property filtration core, the top of the heat dissipation cavity 6 is equipped with feed hopper 3, and the inside of feed hopper 3 is in a rectangular bucket type, internal width Degree is adapted to (mold when molding die 27 is active carbon filter core sintering, by the mixture of carbon dust and glue filling with molding die 27 The inside of molding die 27 can be such that the mixture of carbon dust and glue solidifies in this way after high temperature sintering is cooling, finally become and live Property filtration core), it is low among bottom, in this way after most low molding die 27 is transferred to by material toggling block 10, the molding die of upside 27 will roll down to automatically at material toggling block 10, to save artificial blowing, realize more automatic streamline flow chart, it is described into The inner lower of hopper 3 is equipped with material toggling block 10, and the side wall of material toggling block 10 is equipped with multiple shift plates, each when material toggling block 10 rotates Shift plate all can a secondary volume a molding die 27 fall into blowing area 9, such as when on material toggling block 10 there are four shift plate, material toggling block When 10 90 degree of every rotation, just has a molding die 27 and transferred to by shift plate, after material toggling block 10 does not rotate, molding die 27 is just It can be stored in the inside of feed hopper 3, the side wall of the cabinet 1 is equipped with headstock 2, and the inside of the headstock 2 is provided with cavity 12；

The inside of the heat dissipation cavity 6 and high temperature chamber 5 is rotatablely connected there are two shaft 28, and the inside of the heat dissipation cavity 6 is logical It crosses two shafts 28 and is rotatably connected to the first pierce tap 7 and the second pierce tap 8 respectively, the first pierce tap 7 makes with the second pierce tap 8 It is soft material resistant to high temperature, had both will not influence the firing of active carbon filter core in this way, will not influences to transmit molding die 27 effect, and the effect of the first pierce tap 7 is the effect being sent into molding die 27 inside high temperature chamber 5, the second pierce tap 8 is The sintered molding die 27 of high temperature chamber 5 is sent out to the outside of high temperature chamber 5, the first pierce tap 7 is shorter, and the second pierce tap 8 is longer, The second pierce tap of one end 8 inside high temperature chamber 5 at least grows the width in a blowing area 9, and than the first pierce tap 7 One pierce tap 7 is located at the upside of the second pierce tap 8, and heat dissipation cavity is run through in one end of first pierce tap 7 and the second pierce tap 8 6 side wall and the inside for extending to high temperature chamber 5, and be rotatably connected in the shaft 28 inside high temperature chamber 5；

One end of two shafts 28 inside heat dissipation cavity 6 runs through the side wall of heat dissipation cavity 6 and extends to cavity 12 Internal and be rotatably connected to first gear 13, two engagement connections of first gears 13, the size of two first gears 13 is equal , such first pierce tap 7 is equal with the velocity of rotation that the second pierce tap lives 8, and rotation direction on the contrary, could protect in this way Card is equal with 27 quantity of molding die come out into the molding die 27 inside high temperature chamber 5, so that molding die will not be caused The side wall of 27 accumulation inside high temperature chamber 5, the headstock 2 is equipped with motor 15, and motor 15 is the power source of the device, when When the sliding axle of solenoid valve 18 skids off, motor 15 can be rotated with material toggling block 10, after the sliding axle of solenoid valve 18 retracts, electricity Machine 15 can rotate simultaneously with the first pierce tap 7 and the second pierce tap 8, which is equipped with control panel, can will transport in advance Line program is input to the inside of control panel, such as motor 15 is enclosed with the rotation of material toggling block 10 five by the shaping mould inside feed hopper 3 After tool 27 dials in blowing area 9 in right amount, crosses ten minutes motors 15 and rotated again with the first pierce tap 7 and the second pierce tap 8, the first steel Next blowing area 9 on silk ribbon 7 stops when being in 3 underface of feed hopper, and then motor 15 is again with the rotation of material toggling block 10 five Circle, circuits sequentially, to realize the working cycles of the device, the output shaft of the motor 15 runs through the side wall of headstock 2 and prolongs The inside of cavity 12 is extended to, dark chamber 19 is provided on the side wall of the cavity 12, the inside of the dark chamber 19 is slided by spring 20 It is connected with sliding block 21, when sliding axle bending of the belt 16 between guide wheel 14 and second gear 17 by solenoid valve 18, sliding block 21 Will upward sliding, second gear 17 will be with 21 upward sliding of sliding block when sliding, and second gear 17 will be with after sliding One gear 13 is disengaged from, and motor 15 is rotated with material toggling block 10 at this time, after the sliding axle of solenoid valve 18 is shunk, sliding block 21 It will restore original state by spring 20, such second gear 17 will engage connection with first gear 13, at this time motor 15 It will be rotated with two first gears 13, thus rotated with the first pierce tap 7 and the second pierce tap 8, the sliding block 21 Second gear 17 is fixedly connected on side wall, and second gear 17 engages connection, the sky with 13 activity of first gear of upside Guide wheel 14 is rotatably connected on the side wall of chamber 12, on the output shaft of the motor 15, the central axis and guide wheel 14 of second gear 17 It is rotatably connected to belt 16, the lateral wall of the belt 16 between the second gear 17 and guide wheel 14 and the sliding axle of solenoid valve 18 It is flexibly connected, the sliding axle of solenoid valve 18 and 16 junction of belt are equipped with wheel shaft, reduce rubbing for sliding axle and belt 16 in this way Wipe, the solenoid valve 18 is located at the inside of cavity 12, the inner sidewall of the belt 16 between the second gear 17 and guide wheel 14 with Runner 11 is flexibly connected, the central axis of the runner 11 through cavity 12 side wall and extend to feed hopper 3 inside and with dial Material block 10 is fixedly connected.

Specifically, being equipped with multiple blowing areas 9 on first pierce tap 7 and the second pierce tap 8, and multiple blowing areas 9 is evenly distributed, and the first pierce tap 7 is identical as the revolving speed of the second pierce tap 8, in this way when the first pierce tap 7 extends in high temperature chamber 5 When the blowing area 9 of the one end in portion is bent with shaft 28, the corresponding blowing area 9 on the second pierce tap 8 is just being in it just Lower end, the molding die 27 that will fall off are caught, so that molding die 27 is produced high temperature chamber after rotating again by the second pierce tap 8 5 inside.

Specifically, being equipped with baffle 26 between the heat dissipation cavity 6 and high temperature chamber 5, prevent the temperature inside high temperature chamber 5 from dropping It is low, and it is also prevented from the heat dissipation for the molding die 27 that the heat inside high temperature chamber 5 influences on the second pierce tap 8.

Specifically, the inside of the high temperature chamber 5 and be located at the first pierce tap 7 side be rotatably connected to buffer stopper 22, Since there is drop in the upper surface of the first pierce tap 7 and the second pierce tap 8, when molding die 27 is on the first pierce tap 7 It heated, and was easy to break its internal filter core when the molding die 27 of high temperature is fallen, to increase scrapping for filter core Rate, the bottom of buffer stopper 22 are proximate to the second pierce tap 8, can will be on the first pierce tap 7 by the rotation of buffer stopper 22 Molding die 27 is caught, and then for let-down slowly on the second pierce tap 8, the lateral wall of the buffer stopper 22 is equipped with multiple arcs Shape plate 23, arc panel 23 are circumference permutations on buffer stopper 22, tumble on connecing the first pierce tap 7 first of arc panel 23 After molding die 27, the rear end face of adjacent arc panel 23 can choke second molding die 27, it will not be made to fall, with slow The rotation of block 22 is rushed, the opening of the arc panel 23 can be bonded with the first pierce tap 7, and be lower than the upper surface of the first pierce tap 7, this When molding die 27 will fall in the inside of the arc panel 23, so that buffer step be made to recycle, the either end of the buffer stopper 22 It is fixedly connected with the 4th gear 25, the 4th gear 25 engages connection with third gear 24, and the third gear 24 is fixed to be connected It connects in the shaft 28 of the first pierce tap 7, when being rotated backward with the first pierce tap 7 with buffer stopper 22, on the first pierce tap 7 Molding die 27 can be fallen in arc panel 23, and the molding die 27 on arc panel 23 can be with the rotation meeting of buffer stopper 22 Move down, when arc panel 23 it is opening down after, molding die 27 can roll out arc panel 23, can reduce molding die 27 in this way Collision, to reduce scrappage.

Working principle: when the device works, start the power supply of the device, high temperature chamber 5 is warming up to certain temperature by electric heating pump 4 Afterwards, molding die 27 is placed on to the inside of feed inlet 3, the first pierce tap 7 and the second pierce tap 8 rotate, 7 overhead of the first pierce tap Blowing area 9 when being in the underface of feed hopper 3, the sliding axle of solenoid valve 18 will skid off, so that sliding axle be made to head on belt 16 rotate with runner 11, and at this time since the belt 16 between guide wheel 14 and second gear 17 is bent, second gear 17 be will be with 21 upward sliding of sliding block, so that second gear 17 be made to be disengaged from first gear 13, such motor 15 will be only with runner 11 Rotation, runner 11 can be rotated with material toggling block 10, thus make molding die 27 inside feed hopper 3 one by one push blowing The inside in area 9, when molding die 27 is filled in blowing area 9, solenoid valve 18 withdraws sliding axle, and belt 16 and runner 11 are de- at this time From connection, and second gear 17 engages connection with first gear 13 again, can be with the first pierce tap when such motor 15 rotates 7 rotate together (the first pierce tap 7 is opposite with the rotation direction of the second pierce tap 8) with the second pierce tap 8, just realize in this way One pierce tap 7 brings molding die 27 to be fired into high temperature chamber 5, and the second pierce tap 8 takes the molding die 27 baked out of High temperature chamber 5, and the molding die 27 taken out of through the second pierce tap 8 understands the inside in heat dissipation cavity 6 and is located at the first pierce tap 7 Lower section natural cooling, the molding die 27 sintered in this way is in heat dissipation, by the molding to be sintered on the first pierce tap 7 Mold 27 preheats, so that thermal energy when heat dissipation adequately be utilized, substantially reduces the cost of sintering activity filtration core process.

It although an embodiment of the present invention has been shown and described, for the ordinary skill in the art, can be with A variety of variations, modification, replacement can be carried out to these embodiments without departing from the principles and spirit of the present invention by understanding And modification, the scope of the present invention is defined by the appended.

Claims (6)

1. a kind of automation cycle sintering device for sintering activity filtration core, including cabinet (1), it is characterised in that: described The inside of cabinet (1) from left to right successively opens heat dissipation cavity (6) and high temperature chamber (5), and the upper surface of the high temperature chamber (5) is equipped with The top of electric heating pump (4), the heat dissipation cavity (6) is equipped with feed hopper (3), and the inner lower of the feed hopper (3) is equipped with material toggling block (10), the side wall of the cabinet (1) is equipped with headstock (2), and the inside of the headstock (2) is provided with cavity (12)；

The inside of the heat dissipation cavity (6) and high temperature chamber (5) be rotatablely connected there are two shaft (28), the heat dissipation cavity (6) it is interior Portion is rotatably connected to the first pierce tap (7) and the second pierce tap (8), and first pierce tap by two shafts (28) respectively (7) it is located at the upside of the second pierce tap (8), heat dissipation cavity is run through in first pierce tap (7) and the one end of the second pierce tap (8) (6) side wall and the inside for extending to high temperature chamber (5), and be rotatably connected in the internal shaft (28) of high temperature chamber (5)；

One end of two shafts (28) internal positioned at heat dissipation cavity (6) runs through the side wall of heat dissipation cavity (6) and extends to cavity (12) it inside and is rotatably connected to first gear (13), two first gears (13) engagement connections, the side of the headstock (2) Wall is equipped with motor (15), and the output shaft of the motor (15) runs through the side wall of headstock (2) and extends to the interior of cavity (12) Portion is provided with dark chamber (19) on the side wall of the cavity (12), and the inside of the dark chamber (19) is slidably connected by spring (20) Sliding block (21) is fixedly connected with second gear (17) on the side wall of the sliding block (21), and the of second gear (17) and upside One gear (13) activity engagement connects, and is rotatably connected to guide wheel (14) on the side wall of the cavity (12), the motor (15) Be rotatably connected to belt (16) on output shaft, the central axis of second gear (17) and guide wheel (14), the second gear (17) with The lateral wall of belt (16) between guide wheel (14) is flexibly connected with the sliding axle of solenoid valve (18), and the solenoid valve (18) is located at The inside of cavity (12), the inner sidewall of the belt (16) between the second gear (17) and guide wheel (14) and runner (11) activity Connection, the central axis of the runner (11) through cavity (12) side wall and extend to feed hopper (3) inside and with material toggling block (10) it is fixedly connected.

2. a kind of automation cycle sintering device for sintering activity filtration core according to claim 1, feature exist In: multiple blowing areas (9) are equipped on first pierce tap (7) and the second pierce tap (8), and multiple blowing areas (9) are uniform Arrangement.

3. a kind of automation cycle sintering device for sintering activity filtration core according to claim 1, feature exist In: baffle (26) are equipped between the heat dissipation cavity (6) and high temperature chamber (5).

4. a kind of automation cycle sintering device for sintering activity filtration core according to claim 1, feature exist In: the high temperature chamber (5) inside and be located at the side of the first pierce tap (7) and be rotatably connected to buffer stopper (22), the buffering The lateral wall of block (22) is equipped with multiple arcs plate (23), and the either end of the buffer stopper (22) is fixedly connected with the 4th gear (25), the 4th gear (25) engages connection with third gear (24), and the third gear (24) is fixedly connected on the first steel In the shaft (28) of silk ribbon (7).

5. a kind of automation cycle sintering device for sintering activity filtration core according to claim 4, feature exist In: around buffer stopper (22), circumferentially shape arranges multiple arc panels (23).

6. a kind of automation cycle sintering device for sintering activity filtration core according to claim 1, feature exist In: the sliding axle of the solenoid valve (18) and the junction of belt (16) are equipped with wheel shaft.