CN217773897U - Double-side barrel production mixer - Google Patents

Abstract

The utility model discloses a bilateral bucket production blendor relates to mechanical equipment technical field, aims at solving the not good problem of effect of mixing of traditional blendor to the material. The key points of the technical scheme are as follows: throw the material piece including top-down communicates in proper order, material mixing piece and material receiving part, the material mixing piece has seted up the material mixing chamber along vertical running through, receive material piece open-top, the discharge end of throwing the material piece is equipped with first compounding portion, the compounding intracavity is equipped with the second compounding portion of being connected with the transmission of first compounding portion, throw material open-top and its internal separation for mutually independent first material chamber and second material chamber, the discharge end in first material chamber and second material chamber all communicates with first compounding portion. The utility model discloses a setting up of structure can realize the homogeneous mixing to different materials, and then ensures that the product that produces everywhere quality homogeneous phase, and then improves the product quality who produces.

Description

Double-side barrel production mixer

Technical Field

The utility model relates to a mechanical equipment technical field, more specifically say, it relates to a bilateral bucket production blendor.

Background

The barrel, the utensil for holding water or other things, has a large depth and is made of metal, wood or plastic.

Along with the continuous improvement of productivity level, the use of plastic material's bucket is more and more common, bilateral bucket is a packing barrel that daily life and chemical industry are commonly used, present bilateral bucket is mostly dark blue in order to satisfy the demand of using usually, therefore not only need use white raw materials in the in-process of production, still need to incorporate the coloured material of certain proportion, the component and the nature diverse of coloured material and white raw materials, therefore the even degree of these two kinds of materials mixtures can influence the quality of the bilateral bucket of final product, usually can pour coloured material and white material into stirring structure simultaneously among the prior art, this makes both very difficult misce bene well usually, therefore it is necessary to set up a structure that can improve the even degree of raw materials misce in the bilateral bucket production process.

Therefore, a new solution is needed to solve this problem.

SUMMERY OF THE UTILITY MODEL

Not enough to prior art exists, the utility model aims to provide a bilateral bucket production blendor reaches the purpose that improves the misce bene degree between the different materials through setting up of structure.

The above technical purpose of the present invention can be achieved by the following technical solutions: this bilateral bucket production blendor, including top-down's the material piece of throwing, material mixing and the material receiving part that communicates in proper order, the material mixing chamber has been seted up along vertical running through to the material mixing part, the material receiving part open-top, the discharge end of throwing the material piece is equipped with first compounding portion, the compounding intracavity is equipped with the second compounding portion of being connected with the transmission of first compounding portion, throw material piece open-top and its internal separation for first material chamber and second material chamber independent each other, the discharge end in first material chamber and second material chamber all communicates with first compounding portion.

The utility model discloses further set up to: the material mixing cavity is internally and fixedly connected with a plurality of support frames, the support frames are rotatably connected with drive rods for driving the first material mixing part and the second material mixing part to move, and the bottom of each drive rod is fixedly connected with a drive motor for driving the drive rods to rotate.

The utility model discloses further set up to: the first material mixing part comprises a spiral material feeding sheet fixedly connected with the top end of the driving rod and a material feeding pipe sleeved outside the spiral material feeding sheet, a first blanking gap is arranged between the spiral material feeding sheet and the material feeding pipe in an enclosing mode, and the spiral material feeding sheet is used for pushing materials in the material feeding pipe to slide upwards.

The utility model discloses further set up to: the second material mixing part comprises a plurality of stirring sheets fixedly connected with the driving rod and a stirring pipe fixedly connected with the bottom ends of the stirring sheets, and a second blanking gap is formed between the stirring pipe and the wall of the material mixing cavity in an enclosing mode.

The utility model discloses further set up to: the height of the top surface of the stirring sheet is increased progressively along the direction from the cavity wall of the mixing cavity to the center line of the mixing cavity, and a plurality of stirring strips are fixedly connected to the top surface of the stirring sheet and the side wall of the stirring pipe.

The utility model discloses further set up to: the bottom of the supporting frame positioned below is fixedly connected with a shielding material guiding piece positioned above the driving motor.

The utility model discloses further set up to: the wall of the mixing cavity between every two adjacent stirring sheets is fixedly connected with a plurality of connecting rods, one side, far away from the wall of the mixing cavity, of each connecting rod is fixedly connected with an air guide ring pipe, a plurality of air outlets are formed in the air guide ring pipe, an air supply pipe penetrating out of the mixing piece is communicated with the air guide ring pipe, and an air pump is communicated with the air supply pipe.

To sum up, the utility model discloses following beneficial effect has:

different materials are respectively put into a first material cavity and a second material cavity, a driving motor and an air pump are started, the driving motor rotates to drive a driving rod to rotate, the air pump generates flowing air and sends the flowing air into an air supply pipe, the air in the air supply pipe is led into an air guide ring pipe, the air in the air guide ring pipe flows out from an air outlet and is led into a material mixing cavity, the driving rod rotates to drive a spiral feeding piece to rotate, the materials in the first material cavity and the second material cavity fall into the material supply pipe under the action of self gravity, the driving rod drives the spiral feeding piece to rotate in the process and can stir and mix the materials, the materials in the material supply pipe fall from the bottom of the material supply pipe from a first blanking gap, the falling materials fall onto a stirring sheet and a stirring pipe which are located above, the stirring sheet and the stirring pipe rotate under the driving of the driving rod, the stirring sheet and the stirring pipe rotate in the process to drive a stirring strip to rotate and realize stirring and mixing of the materials, the materials cross the first stirring pipe and the stirring sheet from a second blanking gap, the materials can be further stirred and can be prevented from falling onto another material mixing pipe after the materials and the materials are prevented from falling from being blocked and falling onto the stirring sheet.

Drawings

FIG. 1 is a schematic view of the present invention;

fig. 2 is a cross-sectional view of the present invention;

FIG. 3 is an enlarged view at A in FIG. 2;

FIG. 4 is an enlarged view at B in FIG. 2;

fig. 5 is an enlarged view at C in fig. 2.

In the figure: 1. feeding the material; 2. mixing parts; 3. receiving a material part; 4. a mixing chamber; 5. a first material cavity; 6. a second material chamber; 7. a support frame; 8. a drive rod; 9. a drive motor; 10. spirally feeding the material sheets; 11. a feeding pipe; 12. a first blanking gap; 13. a stirring sheet; 14. a stirring pipe; 15. a second blanking gap; 16. stirring strips; 17. shielding the material guide piece; 18. a connecting rod; 19. an air guide ring pipe; 20. an air outlet; 21. an air supply pipe; 22. an air pump.

Detailed Description

The present invention will be described in detail with reference to the accompanying drawings and examples.

This bilateral bucket production blendor, as shown in fig. 1-fig. 3, throw material 1 including top-down intercommunication in proper order, material mixing 2 and receive material 3, material mixing 2 has seted up material mixing chamber 4 along vertical running through, material mixing 2's bottom fixedly connected with and receive material 3 in a plurality of supporting legs of bottom surface fixed connection, receive material 3 open-top, the discharge end of throwing material 1 is equipped with first compounding portion, be equipped with the second compounding portion of being connected with first compounding portion transmission in the material mixing chamber 4, through the depositing of material mixing chamber 4 to second compounding portion, ensure the steady and smooth and easy of second compounding portion compounding process, be provided with the process of first compounding portion and second compounding portion two-pass compounding simultaneously, make the structure whole can realize many times the compounding to different materials, ensure the degree that the material mixes more evenly, throw material 1 open-top and its inside first material chamber 5 and second material chamber 6 that mutually independent, the discharge end of first material chamber 5 and second material chamber 6 all communicates with first compounding portion, be provided with mutually independent first material chamber 5 and second material chamber and the material chamber that the material storage can be different from the material mixing portion of falling well, the material storage of the first compounding portion and second material chamber can be different.

As shown in fig. 2 and 5, a plurality of support frames 7 are fixedly connected in the material mixing cavity 4, a drive rod 8 for driving the first material mixing part and the second material mixing part to move is rotatably connected to each support frame 7, stable support for the drive rod 8 can be realized by a plurality of support members, it is ensured that the drive rod 8 rotates and drives the material smoothly, the bottom fixedly connected with of the drive rod 8 drives a drive motor 9 for driving the drive rod 8 to rotate, the drive motor 9 can drive the drive rod 8 to rotate in the rotating process, the drive rod 8 rotates to drive the first material mixing part and the second material mixing part to move and stir and mix the material, the bottom fixedly connected with of the support frame 7 below is located above the drive motor 9 and is provided with a shielding material guide 17, the height of the whole top surface of the shielding material guide 17 is gradually reduced from the middle of the shielding material guide 17 to the periphery, the material falling to the top surface of the shielding material guide 17 can receive the component force of the material along the direction of the top surface of the shielding material guide 17, so that the material can slide down from the top surface of the shielding material of the drive motor 9, and ensure the smooth driving motor driving function of the drive motor 9.

As shown in fig. 2 and fig. 3, the first mixing portion includes a spiral material feeding sheet 10 fixedly connected to the top end of the driving rod 8 and a material feeding pipe 11 sleeved outside the spiral material feeding sheet 10, a first blanking gap 12 is defined between the spiral material feeding sheet 10 and the material feeding pipe 11, the spiral material feeding sheet 10 is used for pushing materials in the material feeding pipe 11 to slide upwards, the first blanking gap 12 is used for ensuring that the materials can cross the spiral material feeding sheet 10 and fall downwards, the driving rod 8 can drive the spiral material feeding sheet 10 to rotate in the rotating process, the spiral material feeding sheet 10 can push partial materials in the pipe cavity of the material feeding pipe 11 to move upwards in the rotating process, so that the materials can slide out from the material feeding pipe 11 in a delayed manner, and meanwhile, the spiral material feeding sheet 10 can stir and mix the materials in the rotating process in the material feeding pipe 11, so that different materials can be mixed better.

As shown in fig. 2 to fig. 4, the second material mixing portion includes a plurality of stirring blades 13 fixedly connected to the driving rod 8 and a stirring pipe 14 fixedly connected to a bottom end of the stirring blades 13, a second blanking gap 15 is defined between the stirring pipe 14 and a cavity wall of the material mixing cavity 4, the driving rod 8 drives the stirring blades 13 and the stirring pipe 14 fixedly connected thereto to rotate in a rotating process, and further drives the materials to rotate through rotation of the stirring blades 13 and the stirring pipe 14, so as to achieve stable mixing between different materials, the second blanking gap 15 is formed to allow the materials to cross the stirring blades 13 and the stirring pipe 14, so as to ensure stable implementation of a downward sliding process of the materials, a height of a top surface of the stirring blades 13 increases gradually along the cavity wall of the material mixing cavity 4 toward a center line of the material mixing cavity 4, and the setting enables the materials falling to a top surface of the stirring blades 13 to be subjected to a component force of the gravity of the materials along the top surface of the stirring blades 13, so that the materials can better slide along the top surface of the stirring blades 13, the top surface of the stirring blades 13 and a side wall of the stirring pipe 14 are fixedly connected to a plurality of stirring blades 16, and the stirring pipe 14 can better drive the materials to rotate in a uniform mixing process, and to more uniform mixing of materials and to mix materials.

As shown in fig. 2-4, a plurality of connecting rods 18 are fixedly connected to the cavity wall of the mixing cavity 4 between two adjacent stirring blades 13, an air guide ring tube 19 is fixedly connected to one side of each connecting rod 18, which is far away from the cavity wall of the mixing cavity 4, a plurality of air outlets 20 are formed in the air guide ring tube 19, an air supply tube 21 penetrating through the mixing part 2 is communicated with the air guide ring tube 19, an air pump 22 is communicated with the air supply tube 21, flowing air can be generated after the air pump 22 is started, the flowing air is supplied into the air supply tube 21, the flowing air enters the air guide ring tube 19 under the conveying action of the air supply tube 21, under the drainage action of the air guide ring tube 19, the flowing air flows to the plurality of air outlets 20, the air in the air guide ring tube 19 flows out from the air outlets 20 and blows towards the falling materials, so that different materials can be further scattered and mixed, the mixing uniformity among the plurality of materials is improved, and the overall quality of the subsequently produced barrel body is further improved.

The working principle is as follows: different materials are respectively put into the first material cavity 5 and the second material cavity 6, the driving motor 9 and the air pump 22 are started, the driving motor 9 rotates to drive the driving rod 8 to rotate, the air pump 22 generates flowing air to be fed into the air feeding pipe 21, the air in the air feeding pipe 21 is fed into the air guide ring pipe 19, the air in the air guide ring pipe 19 flows out from the air outlet 20 and is fed into the material mixing cavity 4, the driving rod 8 rotates to drive the spiral material feeding piece 10 to rotate, the materials in the first material cavity 5 and the second material cavity 6 fall into the material feeding pipe 11 under the action of self gravity, the materials can be stirred and mixed in the process that the driving rod 8 drives the spiral material feeding piece 10 to rotate, the materials in the material feeding pipe 11 fall from the bottom of the material feeding pipe 11 from the first blanking gap 12, the falling materials fall onto the stirring piece 13 and the stirring pipe 14 which are positioned above, stirring piece 13 and stirring pipe 14 rotate under the drive of actuating lever 8, stirring piece 13 and stirring pipe 14 pivoted in-process drive stirring strip 16 rotate and realize stirring and mixing to the material, the material is crossed first stirring pipe 14 and stirring piece 13 from second blanking clearance 15, the material can receive the mobile air that flows from gas outlet 20 when falling down from first stirring pipe 14 below, make the material further break up and fall to another stirring piece 13 and stirring pipe 14 after mixing on, make the material stir once more and mix, the material can fall to sheltering from on the baffle guide 17 after crossing stirring pipe 14 once more, make the material fall to receiving 3 under the effect of sheltering from the guide 17 guide and receive in, the aforesaid is just for the utility model discloses an theory of operation.

It is above only the utility model discloses a preferred embodiment, the utility model discloses a scope of protection does not only confine above-mentioned embodiment, the all belongs to the utility model discloses a technical scheme under the thinking all belongs to the utility model discloses a scope of protection. It should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims (7)

1. The utility model provides a bilateral bucket production blendor which characterized in that: the feeding device comprises a feeding part (1), a mixing part (2) and a receiving part (3) which are sequentially communicated from top to bottom, wherein the mixing part (2) is vertically penetrated through to form a mixing cavity (4), the receiving part (3) is provided with an open top, the discharging end of the feeding part (1) is provided with a first mixing part, a second mixing part connected with the first mixing part in a transmission manner is arranged in the mixing cavity (4), the open top of the feeding part (1) is internally divided into a first material cavity (5) and a second material cavity (6) which are mutually independent, and the discharging ends of the first material cavity (5) and the second material cavity (6) are communicated with the first mixing part.

2. The double-sided bucket production blender of claim 1, wherein: a plurality of support frames (7) of fixedly connected with in the material mixing chamber (4), it is connected with actuating lever (8) that drive first material mixing portion and the motion of second material mixing portion to rotate on support frame (7), the bottom fixedly connected with of actuating lever (8) drives actuating lever (8) pivoted driving motor (9).

3. The double-sided bucket production blender of claim 2, wherein: the first material mixing part comprises a spiral material feeding sheet (10) fixedly connected with the top end of the driving rod (8) and a material feeding pipe (11) sleeved outside the spiral material feeding sheet (10), a first blanking gap (12) is arranged between the spiral material feeding sheet (10) and the material feeding pipe (11) in an enclosing mode, and the spiral material feeding sheet (10) is used for pushing materials in the material feeding pipe (11) to slide upwards.

4. A double-sided bucket production blender as defined in claim 3 in which: the second material mixing part comprises a plurality of stirring sheets (13) fixedly connected with the driving rod (8) and a stirring pipe (14) fixedly connected with the bottom ends of the stirring sheets (13), and a second blanking gap (15) is formed between the stirring pipe (14) and the wall of the material mixing cavity (4).

5. The double-sided bucket production blender of claim 4, wherein: the height of the top surface of the stirring sheet (13) is gradually increased along the direction from the cavity wall of the mixing cavity (4) to the central line of the mixing cavity (4), and a plurality of stirring strips (16) are fixedly connected to the top surface of the stirring sheet (13) and the side wall of the stirring pipe (14).

6. The double-sided bucket production blender of claim 2, wherein: the bottom of the supporting frame (7) positioned below is fixedly connected with a shielding material guiding piece (17) positioned above the driving motor (9).

7. The double-sided bucket production blender of claim 4, wherein: the material mixing device is characterized in that a plurality of connecting rods (18) are fixedly connected to the wall of the material mixing cavity (4) between every two adjacent stirring sheets (13), a plurality of air guide ring pipes (19) are fixedly connected to one sides, far away from the wall of the material mixing cavity (4), of the connecting rods (18), a plurality of air outlets (20) are formed in the air guide ring pipes (19), air supply pipes (21) penetrating out of the material mixing part (2) are communicated to the air guide ring pipes (19), and air pumps (22) are communicated to the air supply pipes (21).

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