CN112013653A - Drying equipment is used in preparation of rotation non-road machinery catalyst - Google Patents

Abstract

The invention discloses a drying device for manufacturing a rotary non-road mechanical catalyst, which structurally comprises a rotator, a conveyor belt, a fixed seat and a stirring mechanism, wherein the conveyor belt is arranged on the side surface of the rotator and is positioned on the right side of the stirring mechanism, particulate matters enter a semicircular shaft in a stress mechanism so as to be shunted and enter a clearance groove, so that the particulate matters are close to the middle area of the stress mechanism during stirring, the regularity of the particulate matters is enhanced during shunting and closing, the falling particles can be quickly gathered and attached, the attaching heat conduction effect is enhanced, the heating degrees among the particulate matters are consistent, a stress plate is stressed during attaching by the attaching mechanism, the stress plate is bent under the force of an inclined direction, the stress plate is bent, meanwhile, the stress plate is tightly attached under the sliding of the lower end of a fixed block, the generation of gaps is avoided, the particulate matters are prevented from entering, and the grabbing force on the particulate matters is, improve reposition of redundant personnel effect, avoid particulate matter from the dispersion of friction atress in the clearance.

Description

Drying equipment is used in preparation of rotation non-road machinery catalyst

Technical Field

The invention relates to the field of engineering machinery, in particular to drying equipment for manufacturing a rotary non-road mechanical catalyst.

Background

Non-road machinery adopts diesel oil or gasoline as a power source, so that the emission of tail gas of the non-road machinery causes greater environmental pollution, the tail gas is catalyzed by adopting a catalyst, and the metal catalyst has the effects of reducing air resistance, improving power performance and improving tail gas purification efficiency, but a rotary cylinder type dryer adopts a mode of mixing materials with hot air, and is dried downstream, the metal catalyst materials are in friction fit with the inner wall of a cylinder, because platinum metal particles have stronger heat conductivity and are not easy to disperse under stress, the particles are irregularly moved under the action of rotation of a shoveling plate in the cylinder, so that the particles are dispersed at each part of the cylinder, the mutual heat conduction among the particles is not facilitated, the fit holding force of the shoveling plate to the particles is poorer, part of the particles are easy to stay at the lower end of the cylinder, part of the particles are fit with heat conduction, and form, affecting the drying effect.

Disclosure of Invention

The invention is realized by the following technical scheme: the utility model provides a drying equipment is used in preparation of rotation non-road machinery catalyst, its structure is including rotating ware, conveyer belt, fixing base, rabbling mechanism, the conveyer belt is installed in rotating the ware side, the conveyer belt is located the rabbling mechanism right side, the fixing base welding is at the rabbling mechanism lower extreme, the rabbling mechanism is equipped with pan feeding mouth, clearance switch, rotary mechanism, axis of rotation, cylindricality jar, the pan feeding mouth is located cylindricality jar upper end, the clearance switch is installed in cylindricality jar left side, the axis of rotation runs through in cylindricality jar right side, rotary mechanism inlays admittedly at the axis of rotation left end, rotary mechanism and cylindricality jar are located same center axis, cylindricality jar lower extreme welding is in the fixing base upper end, extend to clearance switch left side in the middle of axis.

As a further improvement of the invention, the rotating mechanism is provided with a connecting shaft, fixing rods, stirring shoveling plates and telescopic switches, wherein the fixing rods are positioned outside the connecting shaft, the telescopic switches are embedded and fixed inside the fixing rods, the outer sides of the fixing rods are embedded and fixed inside the stirring shoveling plates, the stirring shoveling plates are attached to the inner side of the cylindrical tank, and the four stirring shoveling plates are annularly surrounded by taking the connecting shaft as a center.

As a further improvement of the invention, the stirring shoveling plate is provided with three corner blocks, a connecting block and two stress mechanisms, wherein the stress mechanisms are welded on two sides of the connecting block, the three corner blocks are positioned outside the stress mechanisms, the connecting block is embedded outside the fixed rod, and the two stress mechanisms are of bent structures with openings facing outwards.

As a further improvement of the invention, the stress mechanism is provided with a semicircular shaft, clearance grooves, an extrusion mechanism and a connecting plate, the semicircular shaft is embedded and fixed on the side surface of the extrusion mechanism, the clearance grooves are positioned on the two sides of the left side of the semicircular shaft, the connecting plate is attached to the lower end of the extrusion mechanism, the connecting plate is positioned on the right side of the triangular block, the clearance grooves are uniformly distributed at intervals, and the surface of the semicircular shaft has sliding force.

As a further improvement of the invention, the extrusion mechanism is provided with a bending plate, a ball body, a sponge block, a fitting mechanism and a stress opening, wherein the bending plate is fitted at the lower end of the sponge block, the ball body is embedded and fixed at the lower side of the bending plate, the stress opening is positioned at the upper end of the fitting mechanism, the fitting mechanism is positioned in the connecting plate, the ball body is distributed in an arc shape, and the stress opening is smaller towards the right.

As a further improvement of the invention, the laminating mechanism is provided with a fixed plate, a fixed block, a stress plate and a spring, the fixed plate is embedded and fixed on the side surface of the fixed block, the spring is welded at the upper end of the fixed block, the spring is embedded and fixed at the lower end of the fixed plate, the fixed plate is positioned at the lower end of the stress opening, the spring can be bent left and right, and the lower end of the fixed block is of a semicircular structure, so that the effect of reducing sliding force is achieved.

Advantageous effects

Compared with the prior art, the invention has the beneficial effects that:

1. inside metal particle gets into the cylindricality jar from the pan feeding mouth, it is rotatory that the rotating ware rotates and drives the fixing base, it stirs to make the axis of rotation drive rotary mechanism, thereby the connecting axle rotates and makes dead lever and stirring flight synchronous revolution, the triangle-shaped piece slides on the cylindricality jar inner wall in rotatory process, the laminating of connecting plate is at cylindricality jar inner wall simultaneously, and two-way atress mechanism makes the counter-rotating also have the stirring effect on every stirring flight, make the particle get into on the semicircle in the atress mechanism is epaxial, thereby the reposition of redundant personnel gets into the interstitial groove, make the particle draw close to atress mechanism middle zone when stirring, draw close the regularity of in-process reinforcing particle in the reposition of redundant personnel, make and fall after can gather together the laminating fast, strengthen its laminating heat.

2. The particulate matter gets into the atress opening in the extrusion mechanism from the relief groove reposition of redundant personnel, because the atress opening is the smaller to the right, the particulate matter carries out the atress on crooked board, make the compression of sponge piece, make the extrusion of laminating each other between the particulate matter, the spheroid is rotatory when the extrusion force is too big between the particulate matter simultaneously, the effect of reinforcing particulate matter laminating heat conduction, the degree of being heated between the particulate matter of messenger is unanimous, laminating mechanism atress board atress in the laminating process, act on the spring when atress board atress is too big, make it receive the power of incline direction crooked, thereby the atress board is crooked, simultaneously atress board atress closely laminates under the slip of fixed block lower extreme, avoid producing the clearance, prevent the particulate matter entering, the reinforcing is to the power of grabbing of particulate matter, the reposition of redundant personnel.

Drawings

FIG. 1 is a schematic structural diagram of a drying apparatus for manufacturing a rotary non-road mechanical catalyst according to the present invention.

Fig. 2 is a schematic side view of a stirring mechanism according to the present invention.

Fig. 3 is a schematic plan view of a rotating mechanism according to the present invention.

FIG. 4 is a schematic plane structure diagram of a stirring shoveling plate according to the present invention.

Fig. 5 is a schematic perspective view of a force-receiving mechanism according to the present invention.

Fig. 6 is a schematic structural diagram of a side surface of an extrusion mechanism according to the present invention.

Fig. 7 is a schematic view of a partial b structure of a bonding mechanism according to the present invention.

In the figure: the device comprises a rotator-1, a conveyor belt-2, a fixed seat-3, a stirring mechanism-4, a feeding port-41, a cleaning switch-42, a rotating mechanism-43, a rotating shaft-44, a cylindrical tank-45, a connecting shaft-431, a fixed rod-432, a stirring shoveling plate-433, a telescopic switch-434, a triangular block-a 1, a connecting block-a 2, a stress mechanism-a 3, a semicircular shaft-a 31, a clearance groove-a 32, a squeezing mechanism-a 33, a connecting plate-a 34, a bending plate-w 1, a sphere-w 2, a sponge block-w 3, a bonding mechanism-w 4, a stress opening-w 5, a fixed plate-w 41, a fixed block-w 42, a stress plate-w 43 and a spring-w 44.

Detailed Description

The technology of the present invention is further described with reference to the accompanying drawings:

example 1:

as shown in fig. 1-5:

the invention relates to a drying device for manufacturing a rotary non-road mechanical catalyst, which structurally comprises a rotator 1, a conveyor belt 2, a fixed seat 3 and a stirring mechanism 4, wherein the conveyor belt 2 is arranged on the side surface of the rotator 1, the conveyor belt 2 is positioned on the right side of the stirring mechanism 4, the fixed seat 3 is welded at the lower end of the stirring mechanism 4, the stirring mechanism 4 is provided with a feeding port 41, a cleaning switch 42, a rotating mechanism 43, a rotating shaft 44 and a cylindrical tank 45, the feeding port 41 is positioned at the upper end of the cylindrical tank 45, the cleaning switch 42 is arranged on the left side of the cylindrical tank 45, the rotating shaft 44 penetrates through the right side of the cylindrical tank 45, the rotating mechanism 43 is fixedly embedded at the left end of the rotating shaft 44, the rotating mechanism 43 and the cylindrical tank 45 are positioned on the same central axis, the lower end of the cylindrical tank 45 is welded at the upper, has a supporting function, so that the force of the rotating mechanism 43 is even, and the stability of the rotating stirring is enhanced.

Wherein, rotary mechanism 43 is equipped with connecting axle 431, dead lever 432, stirring shoveling plate 433, telescopic switch 434, dead lever 432 is located the connecting axle 431 outside, telescopic switch 434 inlays admittedly inside dead lever 432, the outside of dead lever 432 inlays admittedly at stirring shoveling plate 433 inboard, the laminating of stirring shoveling plate 433 is inboard at cylindricality jar 45, stirring shoveling plate 433 is equipped with four to connecting axle 431 encircles as central annular, and stretches out and draws back dead lever 432 through telescopic switch 434, thereby adjusts the laminating degree of stirring shoveling plate 433 and cylindricality jar 45, avoids frictional force too big, prevents to produce the clearance simultaneously and makes the particulate matter smash under stirring shoveling plate 433 frictional force.

The stirring shoveling plate 433 is provided with a triangular block a1, a connecting block a2 and a stress mechanism a3, the stress mechanism a3 is welded on two sides of the connecting block a2, the triangular block a1 is located on the outer side of the stress mechanism a3, the connecting block a2 is fixedly embedded on the outer side of the fixing rod 432, and the stress mechanisms a3 are provided with two bending structures with openings facing outwards, so that particles are drawn close to the middle area of the stress mechanism a3 when being stirred, and are attached together to enhance the thermal conductivity of the particles.

Wherein, atress mechanism a3 is equipped with semicircle axle a31, clearance groove a32, extrusion mechanism a33, connecting plate a34, semicircle axle a31 is embedded in extrusion mechanism a33 side, clearance groove a32 is located semicircle axle a31 left side both sides, connecting plate a34 laminating is at the lower extreme of extrusion mechanism a33, connecting plate a34 is located triangular block a1 right side, clearance groove a32 is the interval evenly distributed, and semicircle axle a31 surface has the sliding force for the particulate matter has better reposition of redundant personnel effect, prevents that the particulate matter from blockking.

The embodiment has the following specific use modes and functions:

in the invention, metal particles enter the cylindrical tank 45 from the feeding port 41, the rotator 1 rotates to drive the fixed seat 3 to rotate, so that the rotating shaft 44 drives the rotating mechanism 43 to stir, the connecting shaft 431 rotates to enable the fixed rod 432 and the stirring shoveling plates 433 to rotate synchronously, the triangular block a1 slides on the inner wall of the cylindrical tank 45 in the rotating process, the connecting plate a34 is attached to the inner wall of the cylindrical tank 45, the bidirectional stress mechanism a3 on each stirring shoveling plate 433 rotates reversely to have a stirring effect, so that the particles enter the semicircular shaft a31 in the stress mechanism a3 and then flow into the clearance groove a32, the particles are enabled to approach to the middle area of the stress mechanism a3 during stirring, the regularity of the particles is enhanced in the flow dividing and approaching process, the falling particles can be quickly gathered and attached, and the attaching and heat conduction effect of the falling particles is enhanced.

Example 2:

as shown in fig. 6-7:

wherein, extrusion mechanism a33 is equipped with crooked board w1, spheroid w2, sponge piece w3, laminating mechanism w4, atress opening w5, crooked board w1 laminates at sponge piece w3 lower extreme, spheroid w2 is inlayed and is fixed at crooked board w1 downside, atress opening w5 is located laminating mechanism w4 upper end, laminating mechanism w4 is located inside connecting plate a34, spheroid w2 presents the arc distribution, and atress opening w5 is the right side opening less for laminating extrusion each other between the particulate matter strengthens its heat conduction effect, and the degree of being heated between the particulate matter of messenger is unanimous.

Wherein, laminating mechanism w4 is equipped with fixed plate w41, fixed block w42, atress board w43, spring w44, a43 inlays fixedly in fixed block w42 side, spring w44 welds in fixed block w42 upper end, spring w44 inlays fixedly at fixed plate w41 lower extreme, fixed plate w41 is located atress opening w5 lower extreme, spring w44 can control the bending, fixed block w42 lower extreme is semi-circular structure, has the effect that reduces the sliding force for atress board w43 acts on spring w44 when atress is too big, makes its atress crooked, thereby atress board w43 atress closely laminates, avoids producing the clearance, strengthens the power of grabbing to the particulate matter, avoids the particulate matter to slide from the clearance.

The embodiment has the following specific use modes and functions:

in the invention, the particulate matters are shunted from the clearance groove a32 to enter the forced opening w5 in the pressing mechanism a33, as the stressed opening w5 is smaller towards the right, the granules are stressed on the bending plate w1, so that the sponge block w3 is compressed, the granules are mutually attached and extruded, meanwhile, when the extrusion force between the particles is too large, the sphere w2 rotates, the effect of the particle bonding heat conduction is enhanced, the heating degree between the particles is consistent, the stress plate w43 of the bonding mechanism w4 is stressed in the bonding process, when the stress plate w43 is stressed excessively, the stress plate w43 acts on the spring w44, so that the stress plate w43 bends due to the stress in the inclined direction, simultaneously the atress of atress board w43 closely laminates under the slip of fixed block w42 lower extreme, avoids producing the clearance, prevents that the particulate matter from getting into, and the reinforcing improves the reposition of redundant personnel effect to the power of grabbing of particulate matter, avoids the particulate matter from the friction atress dispersion in the clearance.

The technical scheme of the invention is utilized, or a similar technical scheme is designed by a person skilled in the art based on the inspiration of the technical scheme of the invention, so that the technical effects are achieved, and the technical scheme and the method fall into the protection scope of the invention.

Claims (6)

1. The utility model provides a rotary drying equipment for non-road machinery catalyst preparation, its structure includes and rotates ware (1), conveyer belt (2), fixing base (3), rabbling mechanism (4), install in rotating ware (1) side conveyer belt (2), conveyer belt (2) are located rabbling mechanism (4) right side, fixing base (3) welding is at rabbling mechanism (4) lower extreme, its characterized in that:

rabbling mechanism (4) are equipped with pan feeding mouth (41), clearance switch (42), rotary mechanism (43), axis of rotation (44), cylindricality jar (45), pan feeding mouth (41) are located cylindricality jar (45) upper end, clearance switch (42) are installed in cylindricality jar (45) left side, axis of rotation (44) run through in cylindricality jar (45) right side, rotary mechanism (43) are inlayed and are fixed in axis of rotation (44) left end, rotary mechanism (43) are located same center axis with cylindricality jar (45), cylindricality jar (45) lower extreme welding is in fixing base (3) upper end.

2. The rotary drying equipment for preparing non-road mechanical catalyst as claimed in claim 1, wherein: the rotary mechanism (43) is provided with a connecting shaft (431), a fixing rod (432), a stirring shoveling plate (433) and a telescopic switch (434), the fixing rod (432) is located on the outer side of the connecting shaft (431), the telescopic switch (434) is embedded and fixed inside the fixing rod (432), the outer side of the fixing rod (432) is embedded and fixed on the inner side of the stirring shoveling plate (433), and the stirring shoveling plate (433) is attached to the inner side of the cylindrical tank (45).

3. The rotary drying equipment for preparing non-road mechanical catalyst as claimed in claim 2, wherein: stirring copy board (433) are equipped with triangle-shaped piece (a1), connecting block (a2), atress mechanism (a3), the both sides at connecting block (a2) are welded in atress mechanism (a3), triangle-shaped piece (a1) are located atress mechanism (a3) outside, connecting block (a2) are embedded and are fixed in dead lever (432) outside.

4. The rotary drying equipment for preparing non-road mechanical catalyst as claimed in claim 3, wherein: force mechanism (a3) is equipped with semicircle axle (a31), clearance groove (a32), extrusion mechanism (a33), connecting plate (a34), semicircle axle (a31) are embedded and are fixed in extrusion mechanism (a33) side, clearance groove (a32) are located semicircle axle (a31) left side both sides, the lower extreme at extrusion mechanism (a33) is laminated in connecting plate (a34), connecting plate (a34) are located triangle piece (a1) right side.

5. The rotary drying equipment for preparing non-road mechanical catalyst as claimed in claim 4, wherein: extrusion mechanism (a33) is equipped with crooked board (w1), spheroid (w2), sponge piece (w3), laminating mechanism (w4), atress opening (w5), crooked board (w1) laminating is at sponge piece (w3) lower extreme, spheroid (w2) are inlayed and are fixed in crooked board (w1) downside, atress opening (w5) are located laminating mechanism (w4) upper end, laminating mechanism (w4) are located inside connecting plate (a 34).

6. The rotary drying equipment for preparing non-road mechanical catalyst as claimed in claim 5, wherein: laminating mechanism (w4) is equipped with fixed plate (w41), fixed block (w42), atress board (w43), spring (w44), a43 inlays admittedly in fixed block (w42) side, spring (w44) welding is in fixed block (w42) upper end, spring (w44) inlays admittedly at fixed plate (w41) lower extreme, fixed plate (w41) are located atress opening (w5) lower extreme.

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