CN113578127A - Catalyst continuous feeding sealing device - Google Patents

Abstract

The invention relates to a sealing device, in particular to a continuous feeding sealing device for a catalyst. It is necessary to design a continuous feeding and sealing device for catalyst, which can rapidly stir the catalyst mixed clear water, save time and labor, has high working efficiency and can continuously feed the catalyst. A catalyst continuous feeding sealing device comprises: the heat dissipation bottom cylinder is provided with a positioning base; the material storage cylinder is arranged on the heat dissipation bottom cylinder; the scale display window is installed on the material storage barrel. This invention allotment mechanism and rabbling mechanism's cooperation down, at first pour proper amount catalyst into the agitator in, the water pump discharges the agitator with the clear water through the catheter in, start servo motor and make the stirring spiral plate rotate and stir clear water and catalyst, and the module that generates heat heats, so, can make people stir catalyst mixing clear water fast, labour saving and time saving, work efficiency is high.

Description

Catalyst continuous feeding sealing device

Technical Field

The invention relates to a sealing device, in particular to a continuous feeding sealing device for a catalyst.

Background

In industrial production, the catalyst is generally used by mixing with clean water and stirring. At present, most people manually stir catalyst mixed clear water, firstly add a proper amount of catalyst into a collection container, then pour a proper amount of clear water, repeatedly stir and mix by a stick, and the hands need to move continuously for a long time, so that the time is long, the labor is hard, and sometimes different catalysts need to be added continuously for stirring, which is troublesome.

How to design one kind and make people stir catalyst mixing clear water fast, labour saving and time saving, work efficiency is high, and gives the continuous feed closing device of catalyst of continuous feed to solve prior art problem.

Disclosure of Invention

In order to overcome the defects that the hands need to move ceaselessly, the time is long, the labor is great, and different catalysts need to be added continuously for stirring sometimes, and the operation is troublesome, the invention aims to provide the continuous catalyst feeding sealing device which enables people to quickly stir the catalyst mixed clear water, saves time and labor, has high working efficiency and can feed the catalyst continuously.

The technical scheme is as follows: a catalyst continuous feeding sealing device comprises: the heat dissipation bottom cylinder is provided with a positioning base; the material storage cylinder is arranged on the heat dissipation bottom cylinder; the scale display window is arranged on the material storage barrel; the material conveying square pipe is arranged on the material storage barrel and communicated with the material storage barrel; the stirring barrel is arranged on the material conveying square pipe and communicated with the material conveying square pipe; the closed cover plate is arranged on the heat dissipation bottom cylinder; the configuration button is arranged on the closed cover plate; the heating button is arranged on the closed cover plate; the adjusting mechanism is arranged on the closed cover plate and used for pumping in clean water; and the stirring mechanism is arranged between the stirring barrel and the heat dissipation bottom barrel and is used for stirring the clean water and the catalyst.

As a further preferable aspect, the dispensing mechanism includes: the clear water tank is arranged on the material storage barrel and sleeved on the material conveying square pipe; the liquid guide pipe is arranged between the clean water tank and the stirring barrel and is communicated with the clean water tank; the water pump is arranged on the liquid guide pipe; the water inlet pipe is arranged on the clear water tank and communicated with the clear water tank; the heating module is arranged on the clear water tank; and the temperature sensor is arranged on the heating module.

As a further preferable mode, the stirring mechanism includes: the positioning underframe is arranged on the stirring barrel; the servo motor is arranged on the positioning underframe; the driving rotating shaft is rotatably arranged on the stirring barrel and fixedly connected with an output shaft of the servo motor; the stirring spiral plate is arranged on the driving rotating shaft; and the liquid level sensor is arranged on the stirring barrel.

As a further preferable scheme, the device further comprises a feeding mechanism, wherein the feeding mechanism comprises: the feeding box is arranged on the closed cover plate; the positioning cam is arranged on the driving rotating shaft; the material baffle plate is arranged on the material loading box in a sliding manner; the booster wheels are rotatably arranged on the material baffle at intervals; the positioning bottom blocks are symmetrically arranged on the feeding box; the guide rod is arranged on the positioning bottom block in a sliding mode and is fixedly connected with the material blocking plate; and the return spring is arranged between the guide rod and the positioning bottom block.

As a further preferable scheme, the device further comprises a batching mechanism, wherein the batching mechanism comprises: the ingredient separation cylinders are symmetrically arranged on the feeding box; the shielding cover is arranged on the feeding box; the connecting bottom block is arranged on the material baffle plate; the guide rail is arranged on the shielding cover; the first driving rack is arranged on the guide rail in a sliding mode and is fixedly connected with the connecting bottom block; the blanking impeller is rotatably arranged on the ingredient separation cylinder; the first driven gear is arranged on one of the blanking impellers and is meshed with the first driving rack; the spring bearings are symmetrically arranged on one of the discharging impellers; the shielding plate is symmetrically arranged between the two ball bearings; the limiting blocks are symmetrically arranged on one of the ingredient separating cylinders; the limiting grooved wheel is arranged on one of the blanking impellers; the limiting clamping rod is arranged on one of the ingredient separating cylinders; the limiting base is arranged on one of the ingredient separating cylinders; the guide connecting rod is arranged on the limiting base in a sliding mode and is fixedly connected with the limiting clamping rod; the limiting spring is arranged between the limiting base and the guide connecting rod; the positioning spring rod is arranged on the guide connecting rod; the adjustable guide seat is arranged on the positioning spring rod in a sliding mode.

As a further preferable scheme, the device further comprises a discharging mechanism, wherein the discharging mechanism comprises: the stress floating plate is arranged on the stirring barrel in a sliding manner; the first pressure sensor is arranged on the stirring barrel; the blanking bottom frame is arranged on the material conveying square pipe; the telescopic electromagnetic valve is arranged on the blanking bottom frame; the second driving rack is arranged on the telescopic electromagnetic valve; the shielding opening-closing plate is symmetrically and rotatably arranged on the blanking bottom frame; the second driven gear is arranged on the shielding opening-closing plate and meshed with the second driving rack; and the second pressure sensor is arranged on the blanking bottom frame.

As a further preferable mode, the device further comprises a filtering mechanism, and the filtering mechanism comprises: the filtering square pipe is arranged on the material conveying square pipe; the filter screens are symmetrically arranged on the filter square pipes; and the guide vane wheel is rotatably arranged on the filtering square pipe.

As a further preferable scheme, the electric control box is further included, the electric control box is installed on one side of the positioning base far away from the scale display window, a switching power supply, a power supply module and a control module are included in the electric control box, the switching power supply supplies power to the sealing device, the power supply module is connected with a power supply main switch through a circuit, and the control module is electrically connected with the power supply module; the control module is connected with a DS1302 clock circuit and a 24C02 circuit; configuration button, heating button, temperature sensor, level sensor, first pressure sensor and second pressure sensor all with control module electric connection, servo motor, flexible solenoid valve, water pump and the module that generates heat all with through peripheral circuit connection.

The invention has the following advantages:

1. this invention allotment mechanism and rabbling mechanism's cooperation down, at first pour proper amount catalyst into the agitator in, the water pump discharges the agitator with the clear water through the catheter in, start servo motor and make the stirring spiral plate rotate and stir clear water and catalyst, and the module that generates heat heats, so, can make people stir catalyst mixing clear water fast, labour saving and time saving, work efficiency is high.

2. According to the invention, under the action of the feeding mechanism, the material baffle plate moves left and right to enable the catalyst to repeatedly fall into the stirring barrel, so that the catalyst can be conveniently and repeatedly added by people.

3. According to the invention, under the action of the filtering mechanism, the filter screen filters impurities, and the guide impeller plays a guiding role, so that impurities remained in the mixture can be avoided.

Drawings

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

Fig. 2 is a partial perspective view of the present invention.

Fig. 3 is a schematic perspective view of a part of the dispensing mechanism of the present invention.

Fig. 4 is a partial perspective view of the stirring mechanism of the present invention.

Fig. 5 is a schematic view of a first partially separated body structure of the feed mechanism of the present invention.

Fig. 6 is an enlarged schematic view of part a of the present invention.

Fig. 7 is a schematic view of a second partial body structure of the feed mechanism of the present invention.

Fig. 8 is a schematic view of a first partial body structure of the dosing mechanism of the present invention.

Fig. 9 is a schematic view of a second partial body structure of the dosing mechanism of the present invention.

Fig. 10 is a perspective view of a third portion of the dispensing mechanism of the present invention.

Fig. 11 is an enlarged view of part B of the present invention.

Fig. 12 is a perspective view of a fourth portion of the dispensing mechanism of the present invention.

Fig. 13 is an enlarged view of part C of the present invention.

Fig. 14 is a schematic view of a first partially separated body structure of the discharging mechanism of the present invention.

Fig. 15 is a second partial body structure schematic diagram of the discharge mechanism of the present invention.

Fig. 16 is a schematic perspective view of a portion of the filter mechanism of the present invention.

Fig. 17 is a circuit block diagram of the present invention.

Fig. 18 is a schematic circuit diagram of the present invention.

Wherein: 1-a heat dissipation bottom cylinder, 2-a positioning base, 3-a stirring barrel, 4-a material conveying square pipe, 5-a material storage cylinder, 51-a scale display window, 6-an electric cabinet, 61-a sealing cover plate, 62-a configuration button, 63-a heating button, 7-a configuration mechanism, 71-a clear water tank, 72-a water pump, 73-a liquid guide pipe, 74-a water inlet pipe, 75-a heating module, 76-a temperature sensor, 8-a stirring mechanism, 81-a positioning bottom frame, 82-a servo motor, 83-a driving rotating shaft, 84-a stirring spiral plate, 85-a liquid level sensor, 9-a feeding mechanism, 91-a feeding box, 92-a positioning cam, 93-a material baffle plate, 94-an auxiliary wheel, 95-a positioning bottom block and 96-a guide rod, 97-a reset spring, 10-a batching mechanism, 101-a batching separating cylinder, 102-a shielding cover, 103-a connecting bottom block, 104-a first driving rack, 105-a guide track, 106-a first driven gear, 107-a blanking impeller, 108-a shielding plate, 109-a marble bearing, 1010-a limiting block, 1011-a limiting sheave, 1012-a limiting clamping rod, 1013-a guide connecting rod, 1014-a limiting base, 1015-a limiting spring, 1016-an adjustable guide seat, 1017-a positioning spring rod, 11-a discharging mechanism, 111-a stressed floating plate, 112-a first pressure sensor, 113-a blanking bottom frame, 114-a telescopic solenoid valve, 115-a second driving rack, 116-a shielding open plate, 117-a second driven gear, 118-a second pressure sensor, 12-a filtering mechanism, 121-a filtering square tube, 122-a filtering net and 123-a guide vane wheel.

Detailed Description

The following further describes the technical solution with reference to specific embodiments, and it should be noted that: the words upper, lower, left, right, and the like used herein to indicate orientation are merely for the location of the illustrated structure in the corresponding figures. The serial numbers of the parts are themselves numbered herein, for example: first, second, etc. are used solely to distinguish one from another as to objects described herein, and do not have any sequential or technical meaning. The application states that: the connection and coupling, unless otherwise indicated, include both direct and indirect connections.

Example 1

A catalyst continuous feeding sealing device is disclosed, as shown in figure 1-figure 4, comprising a heat radiation bottom cylinder 1, a positioning base 2, a mixing tank 3, a material conveying square tube 4, a material storage cylinder 5, a scale display window 51, a sealing cover plate 61, a configuration button 62, a heating button 63, a mixing mechanism 7 and a mixing mechanism 8, wherein the bottom of the heat radiation bottom cylinder 1 is fixedly connected with the positioning base 2, the bottom of the heat radiation bottom cylinder 1 is fixedly connected with the material storage cylinder 5, the right part of the rear side surface of the material storage cylinder 5 is provided with the scale display window 51, the upper part of the material storage cylinder 5 is fixedly connected with the material conveying square tube 4 and communicated with the material conveying square tube 4, the upper part of the material conveying square tube 4 is provided with the mixing tank 3 and communicated with the sealing cover plate 61, the left middle side of the top of the sealing cover plate 61 is fixedly connected with the configuration button 62, the left middle side of the top of the sealing cover plate 61 is fixedly connected with the heating button 63, the heating button 63 is positioned at the front side of the configuration button 62, the mixing mechanism 7 is arranged between the material storage cylinder 5 and the mixing tank 3, a stirring mechanism 8 is arranged between the stirring barrel 3 and the heat dissipation bottom barrel 1.

The adjusting and matching mechanism 7 comprises a clean water tank 71, a water pump 72, a liquid guide pipe 73, a water inlet pipe 74, a heating module 75 and a temperature sensor 76, the clean water tank 71 is fixedly connected to the top of the material storage barrel 5, the clean water tank 71 is sleeved on the material conveying square pipe 4, the liquid guide pipe 73 is arranged between the left side of the clean water tank 71 and the left side of the stirring barrel 3 and communicated with the left side of the stirring barrel, the water pump 72 is arranged on the lower portion of the liquid guide pipe 73, the water inlet pipe 74 is arranged on the front side of the clean water tank 71 and communicated with the front side of the stirring barrel 3, the heating module 75 is fixedly connected to the outer side of the stirring barrel 3 in the circumferential direction, and the temperature sensor 76 is arranged on the inner left side of the heating module 75.

The stirring mechanism 8 comprises a positioning bottom frame 81, a servo motor 82, a driving rotating shaft 83, a stirring spiral plate 84 and a liquid level sensor 85, the positioning bottom frame 81 is fixedly connected to the inner side of the outer top of the stirring barrel 3, the servo motor 82 is arranged in the middle of the positioning bottom frame 81, the driving rotating shaft 83 is rotatably arranged at the circle center of the stirring barrel 3, the top end of the driving rotating shaft 83 is fixedly connected with an output shaft of the servo motor 82, the stirring spiral plate 84 is fixedly connected to the circumferential direction of the lower portion of the driving rotating shaft 83, and the liquid level sensor 85 is fixedly connected to the inner front side face of the stirring barrel 3.

People press a power supply main switch to electrify the sealing device, the liquid level sensor 85 and the temperature sensor 76 send signals, an operator firstly puts the water inlet pipe 74 out of a water pipe, then pours a proper amount of catalyst into the stirring barrel 3, presses the configuration button 62 once to send signals, the control module receives the signals and then controls the water pump 72 to work, the water pump 72 discharges clean water into the stirring barrel 3 through the liquid guide pipe 73, the liquid level sensor 85 monitors the water level, when the water level of the liquid level sensor 85 is higher than a rated value in the control module, the liquid level sensor 85 sends signals, the control module receives the signals and then controls the water pump 72 to stop, then presses the heating button 63 once again, the heating button 63 sends signals, the control module receives the signals and then controls the servo motor 82 and the heating module 75 to work, the servo motor 82 drives the driving rotating shaft 83 to rotate, the driving rotating shaft 83 rotates and drives the stirring spiral plate 84 to rotate, stirring spiral plate 84 rotates and stirs clear water and catalyst, and the module 75 that generates heat heats, and temperature sensor 76 monitors the temperature, and when temperature sensor 76 was higher than the rated value in the control module to the temperature, temperature sensor 76 signals, control servo motor 82 and the module 75 that generates heat after the control module received signal stops, and then the mixture just also through fortune material side pipe 4 discharge deposit the feed cylinder 5 in, people can use the discharge of mixture in the feed cylinder 5.

Example 2

On the basis of embodiment 3, as shown in fig. 5 to 15, the feeding device further includes a feeding mechanism 9, the feeding mechanism 9 includes a feeding box 91, a positioning cam 92, a material blocking plate 93, a power-assisted wheel 94, a positioning bottom block 95, a guide rod 96 and a return spring 97, the feeding box 91 is disposed on the right side of the sealing cover plate 61, the positioning cam 92 is fixedly connected to the upper portion of the driving rotating shaft 83 in the circumferential direction, the material blocking plate 93 is slidably disposed on the left side of the lower portion of the feeding box 91, the power-assisted wheel 94 is rotatably disposed on the left portion of the material blocking plate 93 at intervals, the positioning bottom block 95 is symmetrically disposed on the front and back of the right side of the lower portion of the feeding box 91, the guide rod 96 is slidably disposed in the positioning bottom block 95, the left end of the guide rod 96 is fixedly connected to the right side surface of the material blocking plate 93, and the return spring 97 is disposed between the right end of the guide rod 96 and the right side surface in the positioning bottom block 95.

The automatic material distribution device also comprises a material distribution mechanism 10, wherein the material distribution mechanism 10 comprises a material distribution separating cylinder 101, a shielding cover 102, a connecting bottom block 103, a first driving rack 104, a guide rail 105, a first driven gear 106, a discharging impeller 107, a shielding plate 108, a pin bearing 109, a limiting block 1010, a limiting grooved pulley 1011, a limiting clamping rod 1012, a guide connecting rod 1013, a limiting base 1014, a limiting spring 1015, an adjustable guide seat 1016 and a positioning spring rod 1017, the material distribution separating cylinder 101 is arranged on the left and right of the upper portion in the material loading box 91 symmetrically, the shielding cover 102 is arranged on the lower portion of the outer front side surface of the material loading box 91, the connecting bottom block 103 is fixedly connected to the left portion of the front side surface of the material blocking plate 93, the guide rail 105 is arranged on the lower portion of the shielding cover 102, the first driving rack 104 is arranged on the guide rail 105 in a sliding manner, the first driving rack 104 is fixedly connected with the connecting bottom block 103, the material distribution separating cylinder 101 is provided with the discharging impeller 107 in a rotating manner, the first driven gear 106 is fixedly connected to the front portion of the left discharging impeller 107 in a circumferential direction, the first driven gear 106 is meshed with the first driving rack 104, the front side and the rear side of the left blanking impeller 107 are fixedly connected with the pin bearings 109 along the circumferential direction, the shielding plates 108 are symmetrically arranged between the pin bearings 109 on the front side and the rear side of the left ingredient separating cylinder 101, the front side and the rear side of the left ingredient separating cylinder 101 are fixedly connected with the limiting blocks 1010, the front part of the right blanking impeller 107 is fixedly connected with the limiting grooved pulley 1011 along the circumferential direction, the front side of the lower part of the right ingredient separating cylinder 101 is movably provided with the limiting clamping rod 1012, the limiting clamping rod 1012 is matched with the limiting grooved pulley 1011, the front side of the lower part of the right ingredient separating cylinder 101 is fixedly connected with the limiting base 1014, the front part of the limiting base 1014 is slidably provided with the guide connecting rod 1013, the guide connecting rod 1013 is fixedly connected with the limiting spring 1015 wound between the front side of the bottom of the limiting base 1014 and the lower part of the guide connecting rod 1013, the lower part of the guide connecting rod 1013 is provided with the positioning spring rod 1017, and the adjustable guide seat 1016 is slidably arranged on the positioning spring rod 1017.

Also comprises a discharging mechanism 11, the discharging mechanism 11 comprises a stress floating plate 111, a first pressure sensor 112, a blanking bottom frame 113 and a telescopic electromagnetic valve 114, second drive rack 115, shelter from the open-close plate 116, second driven gear 117 and second pressure sensor 118, lower part slidingtype is equipped with atress kickboard 111 in the agitator 3, the bottom middle part side is equipped with first pressure sensor 112 in the agitator 3, atress kickboard 111 cooperates with first pressure sensor 112, upper portion is equipped with unloading underframe 113 in fortune material side pipe 4, the front portion is equipped with flexible solenoid valve 114 on the left surface in unloading underframe 113, be connected with second drive rack 115 on the flexible solenoid valve 114, unloading underframe 113 middle part rotary type is equipped with two and shelters from open-close plate 116, shelter from open-close plate 116 left part rigid coupling and have second driven gear 117, second driven gear 117 and the meshing of second drive rack 115, unloading underframe 113 left part back downside is equipped with second pressure sensor 118.

Firstly, an operator pours a proper amount of catalyst into the feeding box 91, initially, the material baffle plate 93 limits the catalyst, the return spring 97 is in a compressed state, when the servo motor 82 works, the driving rotating shaft 83 rotates to drive the positioning cam 92 to rotate, the positioning cam 92 rotates to be separated from the material baffle plate 93, due to the effect of the return spring 97, the guide rod 96 drives the material baffle plate 93 to move leftwards, the material baffle plate 93 no longer limits the catalyst, the catalyst also drops into the stirring barrel 3, the driving rotating shaft 83 rotates to be in contact with the material baffle plate 93, the driving rotating shaft 83 drives the material baffle plate 93 to move rightwards, the booster wheel 94 plays a guiding role, the material baffle plate 93 moves rightwards to drive the guide rod 96 to move rightwards, the return spring 97 is compressed, the material baffle plate 93 limits the catalyst, and therefore, the catalyst can be conveniently added repeatedly by people.

Firstly, catalysts with different proper amounts are respectively poured into the left and right ingredient separation cylinders 101, the shielding plate 108 limits the left ingredient separation cylinder 101, the first driving rack 104 enables the adjustable guide seat 1016 to move upwards, the adjustable guide seat 1016 moves upwards to drive the guide connecting rod 1013 to move upwards, the limiting spring 1015 is compressed, the guide connecting rod 1013 moves upwards to drive the limiting clamping rod 1012 to move upwards, the limiting clamping rod 1012 moves upwards to stop limiting the limiting grooved pulley 1011, the catalysts in the right ingredient separation cylinder 101 slide downwards under the action of gravity, when the baffle plate 93 moves leftwards, the baffle plate 93 drives the first driving rack 104 to move leftwards, the first driving rack 104 moves leftwards to separate from the adjustable guide seat 1016, the guide connecting rod 1013 drives the limiting clamping rod 1012 to move downwards under the action of the limiting spring 1015, the limiting clamping rod 1012 moves downwards to limit the limiting grooved pulley 1011, and the right-side catalysts also stop falling, meanwhile, the first driving rack 104 moves leftwards, so that the first driven gear 106 rotates forwards, the first driven gear 106 rotates forwards to drive the marble bearing 109 to rotate forwards, the marble bearing 109 rotates forwards to drive the shielding plate 108 to rotate forwards, the shielding plate 108 rotates forwards to stop limiting the left-side catalyst, the shielding plate 108 rotates forwards to be clamped into the limiting block 1010 to be limited, the marble bearing 109 rotates in the shielding plate 108, the left-side catalyst slides downwards, and therefore the catalyst can be poured into the device according to different proportions.

When the water pump 72 discharges clean water into the stirring barrel 3 through the liquid guide pipe 73, the force bearing floating plate 111 is moved upwards by the clean water, the shielding open-close plate 116 limits the clean water, the liquid level sensor 85 monitors the water level, when the water level of the liquid level sensor 85 is higher than a rated value in the control module, the liquid level sensor 85 sends a signal, the control module receives the signal and then controls the water pump 72 to stop, the heating button 63 is pressed once again, the heating button 63 sends a signal, the control module receives the signal and then controls the servo motor 82 and the heating module 75 to work, the stirring spiral plate 84 rotates to stir the clean water and the catalyst, the heating module 75 heats, the temperature sensor 76 monitors the temperature, when the temperature of the temperature sensor 76 is higher than the rated value in the control module, the temperature sensor 76 sends a signal, and the control module receives the signal and then controls the servo motor 82 and the heating module 75 to stop, and the control module receives the signal and then controls the extension of the telescopic solenoid valve 114, the telescopic solenoid valve 114 drives the second driving rack 115 to move backwards, the second driving rack 115 moves backwards to drive the second driven gear 117 to rotate backwards, the second driven gear 117 rotates backwards to drive the shielding open-close plate 116 to rotate backwards, the shielding open-close plate 116 rotates backwards to stop limiting in a vertical state, the mixture is discharged into the storage barrel 5 through the material conveying square pipe 4, the second driving rack 115 moves backwards to be in contact with the second pressure sensor 118, the second pressure sensor 118 sends a signal, the control module receives the signal and then controls the telescopic solenoid valve 114 to stop, further the mixture is completely discharged to enable the stressed floating plate 111 to move downwards, the stressed floating plate 111 moves downwards to be in contact with the first pressure sensor 112, the first pressure sensor 112 sends a signal, the control module receives the signal and then controls the telescopic solenoid valve 114 to contract for 3 seconds, the telescopic solenoid valve 114 drives the second driving rack 115 to move forwards to reset, the shielding opening-closing plate 116 is also forwardly rotated and reset, and after 3 seconds, the control module controls the telescopic electromagnetic valve 114 to stop, so that the clear water can be limited, and the stirring efficiency is increased.

Example 3

On the basis of the embodiment 1 and the embodiment 2, as shown in fig. 16, the device further includes a filtering mechanism 12, the filtering mechanism 12 includes a filtering square pipe 121, a filtering net 122 and a guide vane wheel 123, the filtering square pipe 121 is disposed at the lower portion of the material conveying square pipe 4, the filtering net 122 is symmetrically and fixedly connected to the inner side surface of the filtering square pipe 121, and the guide vane wheel 123 is rotatably disposed in the filtering square pipe 121.

When the mixture was discharged into in the storage cylinder 5 through fortune material square tube 4, filter screen 122 filtered impurity, and guiding vane wheel 123 played the guide effect, so, can avoid remaining impurity in the mixture.

As shown in fig. 1, 17 and 18, the electric positioning device further comprises an electric cabinet 6, wherein the electric cabinet 6 is installed at the middle side of the front part of the positioning base 2, a switching power supply, a power supply module and a control module are arranged in the electric cabinet 6, the switching power supply supplies power to the sealing device, the power supply module is connected with a power supply main switch through a circuit, and the control module is electrically connected with the power supply module; the control module is connected with a DS1302 clock circuit and a 24C02 circuit; the configuration button 62, the heating button 63, the temperature sensor 76, the liquid level sensor 85, the first pressure sensor 112 and the second pressure sensor 118 are all electrically connected with the control module, and the servo motor 82, the telescopic solenoid valve 114, the water pump 72 and the heating module 75 are all connected with the control module through a peripheral circuit.

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

Claims (8)

1. A catalyst continuous feeding closing device is characterized by comprising:

the heat dissipation bottom cylinder (1), the heat dissipation bottom cylinder (1) is provided with a positioning base (2);

the material storage barrel (5), the material storage barrel (5) is installed on the heat dissipation bottom barrel (1);

the scale display window (51), the scale display window (51) is installed on the material storage barrel (5);

the material conveying square pipe (4), the material conveying square pipe (4) is installed on the material storage barrel (5) and communicated with the material storage barrel;

the stirring barrel (3), the stirring barrel (3) is arranged on the material conveying square pipe (4) and communicated with the material conveying square pipe;

the sealed cover plate (61), the sealed cover plate (61) is installed on the heat-dissipating bottom cylinder (1);

a configuration button (62), wherein the configuration button (62) is installed on the closed cover plate (61);

a heating button (63), wherein the heating button (63) is installed on the closed cover plate (61);

the adjusting mechanism (7) is arranged on the closed cover plate (61) and is used for pumping in clean water;

and the stirring mechanism (8) is arranged between the stirring barrel (3) and the heat dissipation bottom barrel (1) and is used for stirring the clean water and the catalyst.

2. A continuous feeding and closing device for catalyst as claimed in claim 1, wherein the dispensing means (7) comprise:

the clear water tank (71), the clear water tank (71) is installed on the material storage barrel (5), and the clear water tank (71) is sleeved on the material conveying square pipe (4);

the liquid guide pipe (73), the liquid guide pipe (73) is installed between the clear water tank (71) and the stirring barrel (3) and communicated with the clear water tank;

the water pump (72), the water pump (72) is installed on the liquid guide pipe (73);

the water inlet pipe (74), the water inlet pipe (74) is installed on the clear water tank (71) and communicated with the clear water tank;

the heating module (75), the heating module (75) is installed on the clear water tank (71);

and the temperature sensor (76), wherein the temperature sensor (76) is installed on the heating module (75).

3. A continuous feeding and closing device for catalyst as claimed in claim 2, wherein the stirring means (8) comprise:

the positioning underframe (81), the positioning underframe (81) is arranged on the stirring barrel (3);

the servo motor (82), the servo motor (82) is installed on the positioning chassis (81);

the driving rotating shaft (83), the driving rotating shaft (83) is rotatably arranged on the stirring barrel (3), and the driving rotating shaft (83) is fixedly connected with an output shaft of the servo motor (82);

the stirring spiral plate (84), the stirring spiral plate (84) is arranged on the driving rotating shaft (83);

the liquid level sensor (85), liquid level sensor (85) are installed on agitator (3).

4. A continuous feeding and closing device for catalyst as claimed in claim 3, further comprising a feeding mechanism (9), wherein the feeding mechanism (9) comprises:

the feeding box (91), the feeding box (91) is arranged on the closed cover plate (61);

a positioning cam (92), wherein the positioning cam (92) is arranged on the driving rotating shaft (83);

the material blocking plate (93), the material blocking plate (93) is installed on the material loading box (91) in a sliding mode;

the auxiliary wheels (94), the auxiliary wheels (94) are rotatably arranged on the material baffle plate (93) at intervals;

the positioning bottom block (95), the positioning bottom block (95) is symmetrically arranged on the feeding box (91);

the guide rod (96), the guide rod (96) is installed on the positioning bottom block (95) in a sliding mode, and the guide rod (96) is fixedly connected with the material baffle plate (93);

and the return spring (97) is installed between the guide rod (96) and the positioning bottom block (95).

5. A continuous feeding and closing device for catalyst as claimed in claim 4, wherein said device further comprises a dispensing mechanism (10), said dispensing mechanism (10) comprising:

the batching separating cylinder (101), the batching separating cylinder (101) is symmetrically arranged on the feeding box (91);

the shielding cover (102), the shielding cover (102) is arranged on the feeding box (91);

the connecting bottom block (103), the connecting bottom block (103) is arranged on the striker plate (93);

a guide rail (105), the guide rail (105) being mounted on the shield cover (102);

the first driving rack (104), the first driving rack (104) is slidably mounted on the guide track (105), and the first driving rack (104) is fixedly connected with the connecting bottom block (103);

the blanking impeller (107), the blanking impeller (107) is installed on the ingredient separating cylinder (101) in a rotary manner;

the first driven gear (106), the first driven gear (106) is installed on one of the blanking impellers (107), and the first driven gear (106) is meshed with the first driving rack (104);

the pin tumbler bearing (109), the pin tumbler bearing (109) is installed on one of the blanking impellers (107) symmetrically;

the shielding plate (108), the shielding plate (108) is symmetrically installed between the two pin bearings (109);

the limiting block (1010), the limiting block (1010) is symmetrically installed on one of the ingredient separating cylinders (101);

the limiting grooved wheel (1011), the limiting grooved wheel (1011) is installed on one of the blanking impellers (107);

the limiting clamping rod (1012), the limiting clamping rod (1012) is installed on one of the ingredient separation cylinders (101);

the limiting base (1014), the limiting base (1014) is installed on one of the ingredient separating cylinders (101);

the guide connecting rod (1013) is arranged on the limit base (1014) in a sliding manner, and the guide connecting rod (1013) is fixedly connected with the limit clamping rod (1012);

the limiting spring (1015), the limiting spring (1015) is installed between the limiting base (1014) and the guide connecting rod (1013);

the positioning spring rod (1017), the positioning spring rod (1017) is installed on the guide connecting rod (1013);

the adjustable guide seat (1016) is arranged on the positioning spring rod (1017) in a sliding mode.

6. The continuous feeding and sealing device for catalyst as claimed in claim 5, further comprising a discharging mechanism (11), wherein the discharging mechanism (11) comprises:

the stress floating plate (111), the stress floating plate (111) is arranged on the stirring barrel (3) in a sliding way;

the first pressure sensor (112), the first pressure sensor (112) is installed on the mixing tank (3);

the blanking bottom frame (113), the blanking bottom frame (113) is installed on the material conveying square pipe (4);

the telescopic electromagnetic valve (114), the telescopic electromagnetic valve (114) is installed on the blanking bottom frame (113);

the second driving rack (115), the second driving rack (115) is installed on the telescopic solenoid valve (114);

the shielding opening plate (116), the shielding opening plate (116) is symmetrically and rotatably arranged on the blanking bottom frame (113);

the second driven gear (117) is arranged on the shielding opening-closing plate (116), and the second driven gear (117) is meshed with the second driving rack (115);

and the second pressure sensor (118), and the second pressure sensor (118) is installed on the blanking bottom frame (113).

7. A continuous feeding and closing device for catalyst as claimed in claim 6, further comprising a filtering mechanism (12), wherein the filtering mechanism (12) comprises:

the filtering square pipe (121), the filtering square pipe (121) is arranged on the material conveying square pipe (4);

the filter screen (122), the filter screen (122) is symmetrically installed on the filter square pipe (121);

the guide vane wheel (123), guide vane wheel (123) are installed on the square filter tube (121) in a rotary mode.

8. The continuous catalyst feeding and sealing device as claimed in claim 7, further comprising an electric cabinet (6), wherein the electric cabinet (6) is installed at one side of the positioning base (2) far away from the scale display window (51), the electric cabinet (6) internally comprises a switching power supply, a power supply module and a control module, the switching power supply supplies power to the sealing device, the power supply module is connected with a power supply main switch through a circuit, and the control module is electrically connected with the power supply module; the control module is connected with a DS1302 clock circuit and a 24C02 circuit; configuration button (62), heating button (63), temperature sensor (76), level sensor (85), first pressure sensor (112) and second pressure sensor (118) all with control module electric connection, servo motor (82), flexible solenoid valve (114), water pump (72) and generate heat module (75) all with through peripheral circuit connection.

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