CN215540657U - A high-efficient former for producing catalyst carrier - Google Patents

Abstract

The utility model provides high-efficiency forming equipment for producing a catalyst carrier, which comprises a bar extruding machine, a conveyor belt, a plate frame and a collecting box, wherein the conveyor belt is arranged on the bar extruding machine; the plate frame is sequentially provided with a guide roller, a drying device and a cutting mechanism; the drying device comprises a shell, wherein a temperature sensor, a humidity sensor and an infrared heating tube are arranged at the upper part of the inner side of the shell, a gas distribution tube is arranged at the bottom of the inner side of the shell, a gas outlet hole is formed in the gas distribution tube, a gas outlet is formed in the top of the shell, a heat exchange box is further arranged at the top of the shell, a spiral tube penetrates through the heat exchange box, the gas inlet end of the spiral tube is connected to the gas outlet through a pipeline, an air inlet and an air outlet are further formed in the heat exchange box, and a gas exhaust pipe extending to the gas distribution tube is arranged at the gas outlet; the top of the collecting box is provided with a feed inlet, the bottom of the collecting box is provided with a discharge outlet, a conical net cylinder is arranged at the position of the inner part corresponding to the feed inlet, and the bottom of the conical net cylinder is provided with a branch pipe connected with an exhaust pipe. The utility model can efficiently cut the material strips, effectively avoid material loss and has the energy-saving effect.

Description

A high-efficient former for producing catalyst carrier

Technical Field

The utility model belongs to the technical field of catalyst production equipment in the chemical field, and particularly relates to efficient forming equipment for producing a catalyst carrier.

Background

At present, the forming process of the catalyst carrier usually adopts a rotating mode, but the rotating mode easily causes mutual collision between the catalyst carriers to naturally break and form; or when the catalyst carrier is extruded, the catalyst carrier is directly cut into particles by adopting a blade or a steel wire, and the appearance size and the regularity of the cut catalyst carrier are not ideal due to different material conditions, so that the qualified rate of the product is low. For example, when wet granulation is adopted (i.e., the material is directly granulated before being dried), when the material is sticky or the discharge speed is inconsistent, the granulation length is inconsistent, and the influence of the material condition is large; when dry granulation is adopted (i.e., materials are completely dried before being granulated), the physical dimension and regularity of the catalyst carrier are inconsistent due to serious material pulverization and inconsistent discharging speed, and serious dust problems and material loss are brought at the same time.

Therefore, an efficient forming device for producing the catalyst carrier, which has the advantages of regular grain cutting shape, small material loss and less dust, is needed.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the defects of the prior art and provides high-efficiency forming equipment for producing a catalyst carrier, which comprises the following specific scheme:

the efficient forming equipment for producing the catalyst carrier comprises a strip extruding machine, a conveying belt, a plate frame and a collecting box, wherein the strip extruding machine is arranged above the conveying starting end of the conveying belt, the collecting box is arranged below the conveying tail end of the conveying belt, and the conveying belt bypasses above the plate frame when rotating; the plate frame is sequentially provided with a guide roller, a drying device and a cutting mechanism aiming at the material strips; the drying device comprises a shell for the conveyor belt to pass through, a temperature sensor, a humidity sensor and an infrared heating tube are arranged on the upper portion of the inner side of the shell, a gas distribution tube is arranged at the bottom of the inner side of the shell, a plurality of gas outlet holes are formed in the gas distribution tube, an exhaust port is formed in the top of the shell, an exhaust fan is arranged at the exhaust port, a heat exchange box is further arranged at the top of the shell, a spiral tube penetrates through the heat exchange box, the gas inlet end of the spiral tube is connected to the exhaust port through a pipeline, an air inlet and an air outlet are further formed in the heat exchange box, an induced draft fan is arranged at the air inlet, and an exhaust pipe extending to the gas distribution tube is arranged at the air outlet; the top of the collecting box is provided with a feeding hole, the bottom of the collecting box is provided with a discharging hole, the inner part of the collecting box corresponds to the feeding hole and is provided with a conical net cylinder, and the bottom of the conical net cylinder is provided with a branch pipe connected with the exhaust pipe.

Based on the above, dissection mechanism includes the mounting bracket, be equipped with the cylinder on the mounting bracket, the flexible end of cylinder is equipped with the roof, the below of roof is equipped with the bottom plate, connects through many elastic support legs between roof, the bottom plate, has seted up stroke groove and a plurality of location screw hole on the bottom plate, and the bottom plate upside slides and is equipped with a plurality of sliders, set up on the slider with the through-hole that location screw hole corresponds, the slider bottom is equipped with a plurality of passes the connecting rod in stroke groove, the bottom of connecting rod is equipped with the blade, the slider through with the fastening bolt fixed mounting that location screw hole corresponds is on the bottom plate.

Based on the above, all be equipped with flow control valve on blast pipe, the branch pipe.

On the basis, a base plate corresponding to the blade is arranged below the conveying belt on the plate frame.

Compared with the prior art, the utility model has substantive characteristics and progress, and particularly has the following advantages:

1. according to the utility model, the drying device can be designed to efficiently dehumidify the material strips, so that the material strips are in a proper physical state, efficient segmentation treatment is convenient to carry out on the material strips, and material loss can be prevented on the premise of ensuring the molding quality of the catalyst carrier.

2. According to the utility model, the structural design of the collecting box can reduce the impact force on the material particles in the falling process, so that the materials can be efficiently collected, and the collected materials can be conveniently dried.

3. According to the utility model, the structural design of the cutting mechanism can efficiently cut the material strips, and the size of the cut material particles can be flexibly adjusted by adjusting the distance between the sliding blocks.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a schematic structural view of the sectioning mechanism according to the present invention.

In the figure: 1. extruding the strip machine; 2. a conveyor belt; 3. a plate frame; 4. a drying device; 4-1. a shell; 4-2. infrared heating tube; 4-3. temperature sensor; 4-4. a humidity sensor; 4-5, an exhaust port; 4-6, gas distributing pipe; 4-7, a heat exchange box; 4-8, a spiral pipe; 4-9. an air inlet; 4-10, exhaust pipe; 5. a cutting mechanism; 5-1, mounting a frame; 5-2, cylinder; 5-3, top plate; 5-4. elastic support legs; 5-5, a bottom plate; 5-6, sliding block; 5-7, connecting rod; 5-8. a blade; 6. a collection box; 6-1, a feed inlet; 6-2, discharging port; 6-3, conical net cylinder; 6-4, branch pipe; 7. a guide roller; 8. a backing plate.

Detailed Description

The technical solution of the present invention is further described in detail by the following embodiments.

Examples

As shown in fig. 1-2, the present invention provides a high-efficiency forming apparatus for producing a catalyst carrier, comprising a bar extruder 1, a conveyor belt 2, a plate frame 3 and a collection box 6, wherein the bar extruder 1 is arranged above the conveying beginning end of the conveyor belt 2, the collection box 6 is arranged below the conveying end of the conveyor belt 2, and the conveyor belt 2 bypasses above the plate frame 3 when rotating; and the plate frame 3 is sequentially provided with a guide roller 7, a drying device 4 and a cutting mechanism 5 aiming at the material strips.

The drying device 4 is used for dehumidifying the material strips to keep the material strips in a reasonable physical state and comprises a shell 4-1 through which a conveying belt 2 passes, wherein the upper part of the inner side of the shell 4-1 is provided with a temperature sensor 4-3, a humidity sensor 4-4 and an infrared heating tube 4-2, the bottom of the inner side of the shell 4-1 is provided with a gas distribution tube 4-6, the gas distribution tube 4-6 is provided with a plurality of gas outlet holes, the top of the shell 4-1 is provided with a gas outlet 4-5, the gas outlet 4-5 is provided with an exhaust fan, the top of the shell 4-1 is also provided with a heat exchange box 4-7, the heat exchange box 4-7 is provided with a spiral tube 4-8 in a penetrating manner, the gas inlet end of the spiral tube 4-8 is connected to the gas outlet 4-5 through a pipeline, and the heat exchange box 4-7 is also provided with a gas inlet 4-9, And the air inlet 4-9 is provided with an induced draft fan, and the air outlet is provided with an exhaust pipe 4-10 extending to the gas distribution pipe 4-6.

The top of the collecting box 6 is provided with a feeding hole 6-1, the bottom of the collecting box is provided with a discharging hole 6-2, the inner part of the collecting box is provided with a conical net cylinder 6-3 corresponding to the feeding hole 6-1, and the bottom of the conical net cylinder 6-3 is provided with a branch pipe 6-4 connected with the exhaust pipe 4-10.

The cutting mechanism 5 comprises a mounting rack 5-1, a cylinder 5-2 is arranged on the mounting rack 5-1, the telescopic end of the cylinder 5-2 is provided with a top plate 5-3, a bottom plate 5-5 is arranged below the top plate 5-3, the top plate 5-3 and the bottom plate 5-5 are connected through a plurality of elastic supporting legs 5-4, the bottom plate 5-5 is provided with a stroke groove and a plurality of positioning threaded holes, the upper side of the bottom plate 5-5 is provided with a plurality of sliding blocks 5-6 in a sliding manner, the slide block 5-6 is provided with a through hole corresponding to the positioning threaded hole, the bottom of the slide block 5-6 is provided with a plurality of connecting rods 5-7 penetrating through the stroke groove, the bottom of the connecting rod 5-7 is provided with a blade 5-8, and the sliding block 5-6 is fixedly arranged on the bottom plate 5-5 through a fastening bolt corresponding to the positioning threaded hole.

In order to reasonably distribute the heated air discharged from the air outlet, the exhaust pipes 4-10 and the branch pipes 6-4 are respectively provided with a flow control valve.

In order to ensure the efficiency of cutting the material strips, a backing plate 8 corresponding to the blades 5-8 is arranged below the conveyor belt 2 on the plate frame 3.

Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention and not to limit it; although the present invention has been described in detail with reference to preferred embodiments, those skilled in the art will understand that: modifications to the specific embodiments of the utility model or equivalent substitutions for parts of the technical features may be made; without departing from the spirit of the present invention, it is intended to cover all aspects of the utility model as defined by the appended claims.

Claims (4)

1. A high-efficient former for producing catalyst carrier which characterized in that: the automatic conveying device comprises a strip extruding machine (1), a conveying belt (2), a plate frame (3) and a collecting box (6), wherein the strip extruding machine (1) is arranged above a conveying starting end of the conveying belt (2), the collecting box (6) is arranged below a conveying tail end of the conveying belt (2), and the conveying belt (2) bypasses above the plate frame (3) when rotating; a guide roller (7) for the material strips, a drying device (4) and a cutting mechanism (5) are sequentially arranged on the plate frame (3); the drying device (4) comprises a shell (4-1) for the conveyor belt (2) to pass through, a temperature sensor (4-3), a humidity sensor (4-4) and an infrared heating tube (4-2) are arranged on the upper portion of the inner side of the shell (4-1), a gas distribution tube (4-6) is arranged at the bottom of the inner side of the shell (4-1), a plurality of gas outlet holes are formed in the gas distribution tube (4-6), a gas outlet (4-5) is formed in the top of the shell (4-1), an exhaust fan is arranged at the position of the gas outlet (4-5), a heat exchange box (4-7) is further arranged at the top of the shell (4-1), a spiral tube (4-8) penetrates through the heat exchange box (4-7), and the gas inlet end of the spiral tube (4-8) is connected to the gas outlet (4-5) through a pipeline, the heat exchange box (4-7) is also provided with an air inlet (4-9) and an air outlet, an induced draft fan is arranged at the air inlet (4-9), and an exhaust pipe (4-10) extending to the gas distribution pipe (4-6) is arranged at the air outlet; the top of the collecting box (6) is provided with a feeding hole (6-1), the bottom of the collecting box is provided with a discharging hole (6-2), a conical net cylinder (6-3) is arranged at the position corresponding to the feeding hole (6-1) in the collecting box, and the bottom of the conical net cylinder (6-3) is provided with a branch pipe (6-4) connected with the exhaust pipe (4-10).

2. A high-efficiency molding apparatus for producing a catalyst carrier according to claim 1, characterized in that: the cutting mechanism (5) comprises a mounting frame (5-1), a cylinder (5-2) is arranged on the mounting frame (5-1), a top plate (5-3) is arranged at the telescopic end of the cylinder (5-2), a bottom plate (5-5) is arranged below the top plate (5-3), the top plate (5-3) and the bottom plate (5-5) are connected through a plurality of elastic supporting legs (5-4), a stroke groove and a plurality of positioning threaded holes are formed in the bottom plate (5-5), a plurality of sliding blocks (5-6) are arranged on the upper side of the bottom plate (5-5) in a sliding manner, through holes corresponding to the positioning threaded holes are formed in the sliding blocks (5-6), a plurality of connecting rods (5-7) penetrating through the stroke groove are arranged at the bottoms of the sliding blocks (5-6), and blades (5-8) are arranged at the bottoms of the connecting rods (5-7), the sliding blocks (5-6) are fixedly arranged on the bottom plate (5-5) through fastening bolts corresponding to the positioning threaded holes.

3. A high-efficiency molding apparatus for producing a catalyst carrier according to claim 1, characterized in that: flow control valves are arranged on the exhaust pipes (4-10) and the branch pipes (6-4).

4. A high-efficiency molding apparatus for producing a catalyst carrier according to claim 1, characterized in that: and a base plate (8) corresponding to the blades (5-8) is arranged below the conveyor belt (2) on the plate frame (3).

Images