CN216031657U - Environment-friendly stirring machine - Google Patents

Abstract

The utility model discloses an environment-friendly stirrer which comprises a feeding mechanism, a stirring mechanism and a discharging mechanism, wherein the output end of the feeding mechanism is connected with the input end of the stirring mechanism, the output end of the stirring mechanism is connected with the discharging mechanism, the stirring mechanism comprises an outer barrel, a rotating barrel, at least two crushing paddles and at least two stirring paddles, a first driving mechanism for driving the corresponding crushing paddles to rotate so as to crush materials is arranged at the top of each crushing paddle, a second driving mechanism for driving the corresponding stirring paddles to rotate so as to overturn the materials is arranged at the top of each stirring paddle, the rotating directions of the at least two crushing paddles are opposite, and the rotating directions of the at least two stirring paddles are opposite; the discharging mechanism comprises at least one feed opening arranged at the bottom of the rotary barrel, a feed door used for opening or closing the feed opening, and a third driving mechanism used for controlling the opening degree of the feed door. Compared with the prior art, the stirring effect and the stirring efficiency of the stirrer are improved.

Description

Environment-friendly stirring machine

Technical Field

The utility model relates to the technical field of stirring equipment, in particular to an environment-friendly stirrer.

Background

The mixer is a construction machine, and is a machine with blades and a shaft rotating in a drum or a tank to mix and mix a plurality of raw materials into a mixture or proper consistency. The stirring machines are divided into various types, such as a forced stirring machine, a single horizontal shaft stirring machine, a double horizontal shaft stirring machine and the like.

The mixer has extensive use at construction site, for example, when subway construction, can adopt the mixer to stir the earth that will dig out and cement etc. and mix, draws materials on the spot and prepares out the brick that the construction needs, can avoid transporting earth out of the building site, both save time, environmental protection again.

However, in the existing stirring machine, one stirring paddle or more than two stirring paddles rotate in the same direction to directly stir materials, and in the stirring process, the opening degree of a blanking door cannot be controlled according to the material flow to realize blanking while stirring, so that the stirring and mixing effects are poor, and the efficiency is low.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an environment-friendly stirrer, aiming at improving the stirring effect and the blanking efficiency of the stirrer.

In order to achieve the purpose, the utility model provides a stirrer, which comprises a feeding mechanism, a stirring mechanism and a discharging mechanism which are sequentially connected according to a material stirring process, wherein the output end of the feeding mechanism is connected with the input end of the stirring mechanism, the output end of the stirring mechanism is connected with the discharging mechanism, the stirring mechanism comprises an outer barrel, a rotary barrel which is arranged in the outer barrel and used for accommodating materials, at least two crushing paddles and at least two stirring paddles which are arranged in the rotary barrel, a first driving mechanism which is used for driving the corresponding crushing paddles to rotate so as to crush the materials is arranged at the top of each crushing paddle, a second driving mechanism which is used for driving the corresponding stirring paddles to rotate so as to overturn the materials is arranged at the top of each stirring paddle, wherein, the rotation directions of the at least two crushing paddles are opposite, and the rotation directions of the at least two stirring paddles are opposite;

the discharging mechanism comprises at least one feed opening arranged at the bottom of the rotary barrel, a feed door used for opening or closing the feed opening, and a third driving mechanism used for controlling the opening degree of the feed door.

According to a further technical scheme, a barrel cover is arranged on the outer barrel, and a material inlet communicated with the rotary barrel is formed in the barrel cover.

According to a further technical scheme, a feeding funnel and a material metering mechanism for weighing materials are arranged above a barrel cover, the material metering mechanism is located below the feeding funnel, the materials fall from the feeding funnel, and the materials are weighed by the material metering mechanism and then enter the rotary barrel through the material inlet.

According to a further technical scheme, an observation window is formed in one side, opposite to the material inlet, of the barrel cover.

According to a further technical scheme of the utility model, the stirring mechanism further comprises a controller which is respectively connected with the first driving mechanism and the second driving mechanism.

According to a further technical scheme, the discharging mechanism further comprises a rack, and a discharging funnel with an opening at the bottom is fixedly arranged at the bottom of the rack below the rotary barrel.

The utility model further adopts the technical scheme that at least one side of the discharging hopper is provided with a discharging hole.

According to a further technical scheme of the utility model, the outer barrel is mounted on the frame, the third driving mechanism comprises a hydraulic driving system in signal connection with the controller, wherein the hydraulic driving system is mounted at the bottom of the rotary barrel and connected with the blanking door, and the controller is mounted on the frame.

The feeding mechanism comprises a conveying mechanism for conveying materials, and a cover body covering the conveying mechanism, wherein a plurality of light wave heating sheets for preheating the materials are arranged on the inner wall of the cover body.

The further technical scheme of the utility model is that the light wave heating sheet is adhered to the inner wall of the cover body, or is fixedly arranged on the inner wall of the cover body through a fixing structure.

The environment-friendly stirrer has the beneficial effects that: the utility model adopts the technical scheme that the device comprises a feeding mechanism, a stirring mechanism and a discharging mechanism which are sequentially connected according to a material stirring procedure, wherein the output end of the feeding mechanism is connected with the input end of the stirring mechanism, the output end of the stirring mechanism is connected with the discharging mechanism, the stirring mechanism comprises an outer barrel, a rotary barrel which is arranged in the outer barrel and used for accommodating materials, at least two first crushing paddles and at least two first stirring paddles which are arranged in the rotary barrel, the top of each first crushing paddle is provided with a first driving mechanism which is used for driving the corresponding first crushing paddle to rotate so as to crush the materials, the top of each first stirring paddle is provided with a second driving mechanism which is used for driving the corresponding first stirring paddle to rotate so as to overturn the materials, the rotation directions of the at least two first crushing paddles are opposite, and the rotation directions of the at least two first stirring paddles are opposite; discharge mechanism including set up in at least one feed opening of the bottom of rotatory bucket, be used for opening or close the feed door of feed opening and be used for controlling the third actuating mechanism of the degree of opening and shutting of feed door has improved the stirring effect and the stirring efficiency of mixer.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

FIG. 1 is a schematic view of the overall structure of the environmentally friendly blender of the present invention;

FIG. 2 is a schematic view of the overall structure of the stirring mechanism;

FIG. 3 is a schematic view of the overall structure of the stirring mechanism at another angle;

FIG. 4 is a schematic view of the stirring mechanism without the outer barrel and the barrel cover;

FIG. 5 is a schematic view of a first crushing paddle;

fig. 6 is a schematic structural view of a rotary tub;

FIG. 7 is a schematic structural view of a blanking hopper;

fig. 8 is an assembly view of the rotary tub and the discharging hopper;

FIG. 9 is a schematic view of the overall structure of the feed mechanism;

FIG. 10 is a schematic structural view of the feeding mechanism without the housing and the carrying trough;

fig. 11 is a schematic structural view of a fixing structure of the light wave heating sheet.

The reference numbers illustrate:

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Referring to fig. 1 to 11, the present invention provides an environment-friendly mixer, in which a preferred embodiment of the environment-friendly mixer of the present invention includes a feeding mechanism 10, a mixing mechanism 20, and a discharging mechanism 30 connected in sequence according to a material mixing process, wherein an output end of the feeding mechanism 10 is connected to an input end of the mixing mechanism 20, an output end of the mixing mechanism 20 is connected to the discharging mechanism 30, the mixing mechanism 20 includes an outer barrel 201, a rotating barrel 202 installed in the outer barrel 201 and used for accommodating a material, at least two first crushing paddles 203 and at least two first mixing paddles 204 installed in the rotating barrel 202, a first driving mechanism 205 for driving the corresponding first crushing paddles 203 to rotate so as to crush the material is disposed at a top of each first crushing paddle 203, a second driving mechanism 206 for driving the corresponding first mixing paddles 204 to rotate so as to turn over the material is disposed at a top of each first mixing paddle 204, wherein, the rotation directions of the at least two first crushing paddles 203 are opposite, and the rotation directions of the at least two first stirring paddles 204 are opposite.

In this embodiment, the first driving mechanism 205 and the second driving mechanism 206 may be both driving motors or hydraulic motors in the prior art, which is not limited by the utility model.

The material gets into behind rotatory bucket 202, two at least first broken oars 203 are rotatory to opposite direction, smash the material and stir, simultaneously, two at least first stirring oars 204 overturn, stir the material, and cooperate rotatory bucket 202's rotation for the material stirring mixing effect is better, and efficiency is higher.

The discharging mechanism 30 includes at least one discharging opening formed in the bottom of the rotary barrel 202, a discharging door 301 for opening or closing the discharging opening, and a third driving mechanism for controlling the opening degree of the discharging door 301.

When the rotary drum 202 is used, the discharging door 301 can be driven to be opened to a proper opening degree through the third driving mechanism according to the amount of the materials in the rotary drum 202, so that the rotary drum 202 can rotate and discharge materials, and the material stirring effect and the discharging efficiency can be improved.

For example, if there are more materials in the rotary barrel 202, the opening/closing degree of the discharge door 301 may be opened to a smaller degree, so that the material stirring time is longer, and the material is stirred and mixed more uniformly, and if there are fewer materials in the rotary barrel 202, the opening/closing degree of the discharge door 301 may be opened to a larger position, so that the discharging speed is increased, and the discharging speed is increased. Of course, during specific use, the blanking door 301 can be opened to a proper position according to actual requirements, so that the materials are prevented from being accumulated in the rotary barrel 202.

In one embodiment, the number of the first crushing paddles 203 may be three, the number of the first stirring paddles 204 may be two, and in other embodiments, the number may be set according to actual requirements, which is not limited by the present invention.

In this embodiment, the first stirring paddle 204 and the first crushing paddle 203 may be stirring paddles and crushing paddles in the prior art, which is not limited in the present invention.

Preferably, in this embodiment, the first crushing paddle 203 comprises a first driving rod 207 connected to the first driving mechanism 205, and a plurality of crushing blades 208 spirally mounted on the first driving rod 207.

The first stirring paddle 204 comprises a second driving rod 209 connected with the second driving mechanism 206, and a plurality of stirring blades 210 spirally mounted on the second driving rod 209.

In this embodiment, a plurality of optical wave plates (not shown) are uniformly disposed on the inner wall of the rotating barrel 202.

This embodiment is through evenly arrange a plurality of light wave plates on rotatory bucket 202's the inner wall, it is right material in the rotatory bucket 202 is heated the stirring simultaneously, can further improve material stirring and mix effect and efficiency.

Further, in this embodiment, a cover 211 is covered on the outer tub 201, and a material inlet 212 communicated with the rotating tub 202 is opened on the cover 211.

A feeding funnel 213 and a material metering mechanism 214 for weighing the material are arranged above the barrel cover 211, the material metering mechanism 214 is located below the feeding funnel 213, the material falls from the feeding funnel 213, and the material is weighed by the material metering mechanism 214 and then enters the rotary barrel 202 through the material inlet 212.

It should be noted that, in this embodiment, the stirring mechanism 20 further includes a controller 215 connected to the material metering mechanism 214, the first driving mechanism 205 and the second driving mechanism 206, and after the material is weighed by the material metering mechanism 214 and enters the rotating barrel 202, the controller 215 may control the rotating speeds of the first driving mechanism 205 and the second driving mechanism 206 according to the flow rate of the material entering the rotating barrel 202 to stir and mix the material, so as to achieve better stirring effect and stirring efficiency.

It is to be emphasized that, in this embodiment, a cement feeding mechanism 216 is disposed on the barrel cover 211 near the feeding hopper 213, and the cement feeding mechanism 216 is used for feeding cement into the rotary barrel 202. The material can be, for example, soil dug out at a construction site, and the material, namely the soil and the cement are mixed and stirred uniformly in the rotary barrel 202, and then the auxiliary agent is added, so that the material for preparing the brick can be prepared.

An observation window is formed in one side, opposite to the material inlet 212, of the barrel cover 211, and a window door 217 for opening or closing the observation window is arranged on the barrel cover 211, so that the stirring and mixing conditions of the materials in the rotary barrel 202 can be observed conveniently, and the material feeding speed and the rotating speeds of the first driving mechanism 205 and the second driving mechanism 206 are adjusted, so that the stirring effect and the stirring efficiency are further improved. In addition, chemical aids may also be added through the viewing window.

In this embodiment, the number of the feed openings is two, and the two feed openings are symmetrically arranged on two sides of the bottom of the rotary barrel 202.

Further, in this embodiment, the discharging mechanism 30 further includes a frame 302, and a discharging funnel 303 with an open bottom is fixedly disposed at the bottom of the frame 302 below the rotating barrel 202.

Through the discharging hopper 303, the material can be guided, and the material discharged from the rotating barrel 202 is guided to enter the next process.

In this embodiment, at least one side of the discharging funnel 303 is provided with a first discharging hole 304, for example, the two opposite sides of the discharging funnel 303 are respectively provided with the first discharging holes 304, when the discharging speed is fast, the material enters the next process through the first discharging hole 304 and the opening at the bottom of the discharging funnel 303, so as to avoid the material from being accumulated in the rotating barrel 202, and further improve the stirring effect and the discharging efficiency.

Further, in this embodiment, the outer tub 201 is mounted on the frame 302, and the third driving mechanism includes a hydraulic driving system 305 in signal connection with the controller 215, wherein the hydraulic driving system 305 is mounted at the bottom of the rotating tub 202 and connected to the discharge door 301, and the controller 215 is mounted on the frame 302.

The hydraulic drive system 305 adopted in the embodiment has the advantages of small volume, light weight, high rigidity, high precision, high speed response, wide speed regulation range and easy realization of safety protection.

In this embodiment, the feeding mechanism 10 includes a conveying mechanism 101 for conveying the material, and a housing 102 covering the conveying mechanism 101, wherein a plurality of light wave heating plates (not shown in the figure) for preheating the material are disposed on an inner wall of the housing 102. The light wave heating plate is infrared radiation's one kind, and the light wave heating plate can be used as the heat source of the multi-functional drying system of far infrared, and this embodiment is located through covering a plurality of light wave plates are arranged to the inner wall of the cover body 102 of transport mechanism 101, can realize preheating the material in material transportation process, reduce material humidity, can be so that when next process stirs the material, mix more evenly, and then promote stirring mixing effect and efficiency.

In the present embodiment, the light wave heating sheet is relatively thin, and the thickness of the light wave heating sheet is usually only about 5mm, so as to be an embodiment, the light wave heating sheet may be directly adhered to the inner wall of the cover 102.

Further, as an embodiment, in order to avoid damaging the optical wave heating plate during the material conveying process and prolong the service life of the optical wave heating plate, the fixing structure 103 may be fixed to the inner wall of the cover 102 after the optical wave heating plate is fixed by the fixing structure 103.

Specifically, in this embodiment, the fixing structure 103 may be disposed according to the shape of the optical wave heating sheet.

For example, the optical wave heating sheet is a quadrilateral structure, correspondingly, the fixing structure 103 is also a quadrilateral structure, the fixing structure 103 includes two side edges that are arranged in parallel relatively along the length direction, and two fixing edges that are arranged in parallel relatively along the width direction, wherein an insertion slot for fixing the optical wave heating sheet is provided on the inner wall of the two side edges and one of the two fixing edges, and a socket for inserting the optical wave heating sheet is provided on the other fixing edge of the two fixing edges.

When in use, the light wave heating plate is inserted into the slot through the insertion opening, and then the fixing structure 103 is fixed on the inner wall of the cover 102.

In order to make the installation of the optical wave heating plate more stable and reliable, the embodiment is provided with the optical wave heating plate supporting plate between the two side edges and the two fixing edges.

In this embodiment, the conveying mechanism 101 includes a supporting frame 104, a conveying wheel 105 mounted at two ends of the supporting frame 104, and a conveying belt 106 wound around the conveying wheel 105.

The feeding mechanism 10 further comprises a smashing mechanism 107 for smashing the material initially, the output end of the smashing mechanism 107 is located above the conveying mechanism 101, and the material smashed by the smashing mechanism 107 is input to the conveying mechanism 101 from the output end of the smashing mechanism 107.

Specifically, in this embodiment, the output end of the smashing mechanism 107 is located above the conveyor belt 106, and after the materials are smashed and stirred by the smashing mechanism 107, the materials fall onto the conveyor belt 106 through the output end of the smashing mechanism 107, and are conveyed to the next process through the conveyor belt 106 to be stirred and mixed.

More specifically, this embodiment is in smash the below of the output of mechanism 107 and set up the bottom open-ended that is used for bearing the weight of the material and bear funnel 108, conveyer belt 106 is located bear funnel 108's below, the material process smash the output of mechanism 107 and fall into bear funnel 108 back, fall into again conveyer belt 106.

It is worth mentioning that in order to avoid material accumulation, the present invention is further provided with a restrictor plate 110.

Specifically, the present invention is provided with a mounting bracket 109 for mounting the carrying funnel 108, a second discharge hole communicated with the opening of the carrying funnel 108 is provided at the top of the mounting bracket 109, the conveyor belt 106 is located below the second discharge hole, and a restrictor plate 110 is provided at a position corresponding to the second discharge hole on one side of the mounting bracket 109, wherein as an embodiment, the restrictor plate 110 is M-shaped, or has any other shape. In this embodiment, the bottom of the two sides of the restrictor plate 110 may abut the conveyor or have a slight gap to prevent the material from falling out of the two sides, while the side of the conveyor in the transverse direction has a slightly larger gap to the conveyor 106 to facilitate the passage of the material and at the same time not allow the passage of too much material to prevent the material from accumulating.

Specifically, in this embodiment, the crushing mechanism 107 includes a bearing groove 111 for bearing the material, and a second stirring paddle 112 and a second crushing paddle 113 installed in the bearing groove 111.

In the embodiment, the volume of some materials is large, so that the materials are pre-crushed and stirred by the second crushing paddle 113 and the second stirring paddle 112, so as to improve the stirring and mixing effect and efficiency of the stirrer.

The environment-friendly stirrer has the beneficial effects that: the utility model adopts the technical scheme that the device comprises a feeding mechanism, a stirring mechanism and a discharging mechanism which are sequentially connected according to a material stirring procedure, wherein the output end of the feeding mechanism is connected with the input end of the stirring mechanism, the output end of the stirring mechanism is connected with the discharging mechanism, the stirring mechanism comprises an outer barrel, a rotary barrel which is arranged in the outer barrel and used for accommodating materials, at least two first crushing paddles and at least two first stirring paddles which are arranged in the rotary barrel, the top of each first crushing paddle is provided with a first driving mechanism which is used for driving the corresponding first crushing paddle to rotate so as to crush the materials, the top of each first stirring paddle is provided with a second driving mechanism which is used for driving the corresponding first stirring paddle to rotate so as to overturn the materials, the rotation directions of the at least two first crushing paddles are opposite, and the rotation directions of the at least two first stirring paddles are opposite; discharge mechanism including set up in at least one feed opening of the bottom of rotatory bucket, be used for opening or close the feed door of feed opening and be used for controlling the third actuating mechanism of the degree of opening and shutting of feed door has improved the stirring effect and the stirring efficiency of mixer.

The above description is only a preferred embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications and equivalents of the technical solutions of the present invention, which are made by using the contents of the present specification and the accompanying drawings, or directly/indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (10)

1. The environment-friendly stirrer is characterized by comprising a feeding mechanism, a stirring mechanism and a discharging mechanism which are sequentially connected according to a material stirring process, wherein the output end of the feeding mechanism is connected with the input end of the stirring mechanism, the output end of the stirring mechanism is connected with the discharging mechanism, the stirring mechanism comprises an outer barrel, a rotary barrel which is arranged in the outer barrel and used for containing materials, at least two crushing paddles and at least two stirring paddles which are arranged in the rotary barrel, the top of each crushing paddle is provided with a first driving mechanism used for driving the corresponding crushing paddle to rotate so as to crush the materials, the top of each stirring paddle is provided with a second driving mechanism used for driving the corresponding stirring paddle to rotate so as to overturn the materials, and the rotation directions of the at least two stirring paddles are opposite;

the discharging mechanism comprises at least one feed opening arranged at the bottom of the rotary barrel, a feed door used for opening or closing the feed opening, and a third driving mechanism used for controlling the opening degree of the feed door.

2. The environment-friendly stirring machine as claimed in claim 1, wherein the outer barrel is covered with a barrel cover, and the barrel cover is provided with a material inlet communicated with the rotary barrel.

3. The environment-friendly stirring machine as claimed in claim 2, wherein a feeding funnel and a material metering mechanism for weighing the material are arranged above the barrel cover, the material metering mechanism is positioned below the feeding funnel, the material falls from the feeding funnel, and enters the rotary barrel through the material inlet after being weighed by the material metering mechanism.

4. The environment-friendly mixer of claim 2 wherein the lid includes a window on a side opposite the material inlet.

5. The environmentally friendly blender of claim 3 wherein the blending mechanism further comprises a controller coupled to each of the first and second drive mechanisms.

6. The environment-friendly mixer of claim 5 wherein the discharge mechanism further comprises a frame, and a discharge funnel with an open bottom is fixedly arranged at the bottom of the frame below the rotary barrel.

7. The environment-friendly mixer as claimed in claim 6 wherein the discharge hopper is provided with a discharge outlet at least one side thereof.

8. The environment-friendly mixer as claimed in claim 7, wherein the outer tub is mounted on the frame, the third driving mechanism includes a hydraulic driving system in signal connection with the controller, wherein the hydraulic driving system is mounted at the bottom of the rotary tub and connected with the discharging door, and the controller is mounted on the frame.

9. The environment-friendly stirring machine as claimed in claim 1, wherein the feeding mechanism comprises a conveying mechanism for conveying materials, a cover body is covered on the conveying mechanism, and a plurality of light wave heating sheets for preheating the materials are arranged on the inner wall of the cover body.

10. The environment-friendly mixer of claim 9 wherein the optical wave heating plate is adhered to the inner wall of the housing or is fixedly mounted to the inner wall of the housing by a fixing structure.

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