CN210332525U - A compounding system for putty powder production line - Google Patents

Abstract

The utility model provides a compounding system for putty powder production line, it includes preheating tank and second grade powder mixing arrangement, and the preheating tank includes box (1) and reposition of redundant personnel heating mechanism, and second grade powder mixing arrangement includes first box (51), second box (61), gas drive device (52), triangle baffle (62) and a pair of roller (63), the utility model relates to a firing equipment field, concretely relates to a compounding system for putty powder production line. The utility model has the advantages that: 1. waste hot gas on the production line is added into the inverted V-shaped splitter plate to heat various powdery raw materials, waste gas in the production line is utilized, and energy is saved. 2. Through this device both reached the effect of compounding and can also be quick carry out the unloading, simple and convenient, the time of having practiced thrift.

Description

A compounding system for putty powder production line

Technical Field

The utility model relates to a firing equipment field, concretely relates to compounding system for putty powder production line.

Background

At present, 1, my company needs to add multiple powdery raw materials when producing putty powder, because the improvement of technology, need carry out the compounding in adding to the compounding system after heating multiple powdery raw materials, and does not have the device of multiple powdery raw materials heating at present. 2. Putty powder raw materials need can form the product through mixing, stirring and cooling step, and current when mixing, generally all directly stir through the agitator tank, and the agitator tank is in the use, and the time that needs is longer, and the effect of mixing is not good moreover, is in that (mixing) shaft edge position can not carry out fine stirring.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a compounding system for putty powder production line to the not enough of above-mentioned at present.

The utility model comprises a box body and a shunt heating mechanism,

the top of the box body is provided with a feed inlet,

the bottom of the box body is provided with a discharge hole,

an inclined blanking section is arranged at the bottom of the box body, the outlet of the blanking section is communicated with the discharge hole at the bottom of the box body,

the shunt heating mechanism comprises a first layer heating device and a second layer heating device,

the first-layer heating device comprises a first inverted V-shaped flow distribution plate, a heating cavity is arranged in the first inverted V-shaped flow distribution plate, at least one first air inlet and at least one first air outlet are arranged on the box body, the first inverted V-shaped flow distribution plate is arranged in the box body and is positioned below a feed inlet at the top of the box body, the heating cavity in the first inverted V-shaped flow distribution plate is communicated with the at least one first air inlet and the at least one first air outlet on the box body,

the two-layer heating device comprises a second inverted V-shaped flow distribution plate and a third inverted V-shaped flow distribution plate,

heating cavities are respectively arranged in the second inverted V-shaped flow distribution plate and the third inverted V-shaped flow distribution plate, at least one second air inlet, at least one second air outlet, at least one third air inlet and at least one third air outlet are arranged on the box body,

the second inverted V-shaped flow distribution plate is arranged in the box body and is positioned below one inclined plate end point of the first inverted V-shaped flow distribution plate, a heating cavity in the second inverted V-shaped flow distribution plate is communicated with at least one second air inlet and at least one second air outlet on the box body,

a third inverted V-shaped flow distribution plate is arranged in the box body and is positioned below the end point of the other inclined plate of the first inverted V-shaped flow distribution plate, a heating cavity in the third inverted V-shaped flow distribution plate is communicated with at least one third air inlet and at least one third air outlet on the box body,

the second inverted V-shaped flow distribution plate and the third inverted V-shaped flow distribution plate are positioned above the feeding section with the inclined bottom in the box body,

the second-stage powder mixing device comprises a first box body, a second box body, a gas drive device, a triangular baffle plate and a pair of rollers,

the outlet of the first box body and the outlet of the second box body are both provided with an inlet and an outlet, the outlet of the first box body is communicated with the inlet of the second box body,

the air driving device is arranged in the first box body to realize the scattering and mixing of materials through the air driving device,

a triangular baffle is fixedly arranged below the inlet of the second box body,

a group of helical teeth are annularly arrayed on the outer wall of the roller, two ends of a pair of rollers are respectively arranged in the second box body through bearings and respectively drive the pair of rollers to oppositely drive through a motor, a mixture conveying area is formed between the pair of rollers,

two blanking parts of the inclined plane of the triangular baffle are positioned above the pair of rollers,

and the outlet center line of the mixture conveying area and the outlet center line of the second box body are positioned on the same horizontal line.

The inlet of the first box body is communicated with the discharge port arranged at the bottom of the box body.

The outer layer of the box body is provided with heat preservation cotton.

The first inverted V-shaped flow distribution plate, the second inverted V-shaped flow distribution plate and the third inverted V-shaped flow distribution plate are fixedly welded in the box body.

The outer layer of the box body is provided with a steam heating sleeve.

A filter screen is arranged at the feed inlet at the top of the box body.

The end points of the corners of the first inverted V-shaped flow distribution plate are positioned right below the center of the feed inlet at the top of the box body.

One of the inclined plate endpoints of the first inverted V-shaped flow distribution plate is positioned right above the corner endpoint of the second inverted V-shaped flow distribution plate, and the other inclined plate endpoint of the first inverted V-shaped flow distribution plate is positioned right above the corner endpoint of the third inverted V-shaped flow distribution plate.

The air driving device comprises a group of first air nozzles arrayed at the bottom of the box body, and an air outlet of each first air nozzle faces to a feeding port of the first box body.

The air driving device comprises two groups of second air nozzles which are arranged in the box body in a staggered mode, and air outlets of the second air nozzles incline downwards.

The top end point of the triangular baffle is positioned at the center of the inlet of the second box body.

The utility model has the advantages that: 1. waste hot gas on the production line is added into the inverted V-shaped splitter plate to heat various powdery raw materials, waste gas in the production line is utilized, and energy is saved. 2. Through this device both reached the effect of compounding and can also be quick carry out the unloading, simple and convenient, the time of having practiced thrift.

Description of the drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic structural view of a cross section of a preheating tank.

Fig. 3 is a structural schematic diagram of the installation position of the first air nozzle.

FIG. 4 is a schematic view of a second nozzle mounting structure.

FIG. 5 is a schematic view showing a pair of roller mounting positions.

Figure 6 is a schematic view of a roll structure.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, 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 some, but not all, embodiments of the present invention. The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.

In the description of the embodiments of the present invention, it should be noted that, if the terms "upper", "lower", "inside", "outside", etc. are used for indicating the orientations or positional relationships based on the orientations or positional relationships shown in the drawings or the orientations or positional relationships that the products of the present invention usually place when using, the present invention is only used for convenience of description and simplification of the description, but does not indicate or imply that the devices or elements indicated must have specific orientations, be constructed in specific orientations, and operate, and thus, the present invention should not be construed as being limited. Furthermore, the appearances of the terms "first," "second," and the like in the description of the present invention are only used for distinguishing between the descriptions and are not intended to indicate or imply relative importance.

In the description of the embodiments of the present invention, it should be further noted that unless otherwise explicitly stated or limited, the terms "disposed" and "connected" should be interpreted broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

As shown in the figure, the utility model comprises a box body 1 and a shunt heating mechanism,

the top of the box body 1 is provided with a feed inlet,

the bottom of the box body 1 is provided with a discharge hole,

the bottom in the box body 1 is provided with an inclined blanking section 11, the outlet of the blanking section 11 is communicated with the discharge hole at the bottom of the box body 1,

the shunt heating mechanism comprises a first layer heating device and a second layer heating device,

the first-layer heating device comprises a first inverted V-shaped flow distribution plate 2, a heating cavity is arranged in the first inverted V-shaped flow distribution plate 2, at least one first air inlet 12 and at least one first air outlet are arranged on the box body 1, the first inverted V-shaped flow distribution plate 2 is arranged in the box body 1 and is positioned below a feed inlet at the top of the box body 1, the heating cavity in the first inverted V-shaped flow distribution plate 2 is communicated with the at least one first air inlet 12 and the at least one first air outlet on the box body 1,

the two-layer heating device comprises a second inverted V-shaped flow distribution plate 3 and a third inverted V-shaped flow distribution plate 4,

heating cavities are respectively arranged in the second inverted V-shaped flow distribution plate 3 and the third inverted V-shaped flow distribution plate 4, at least one second air inlet 13, at least one second air outlet, at least one third air inlet 14 and at least one third air outlet are arranged on the box body 1,

the second inverted V-shaped flow distribution plate 3 is arranged in the box body 1 and is positioned below one inclined plate end point of the first inverted V-shaped flow distribution plate 2, a heating cavity in the second inverted V-shaped flow distribution plate is communicated with at least one second air inlet 13 and at least one second air outlet on the box body 1,

the third inverted V-shaped flow distribution plate 4 is arranged in the box body 1 and is positioned below the end point of the other inclined plate of the first inverted V-shaped flow distribution plate 2, a heating cavity in the third inverted V-shaped flow distribution plate is communicated with at least one third air inlet 14 and at least one third air outlet on the box body 1,

the second inverted V-shaped flow distribution plate 3 and the third inverted V-shaped flow distribution plate 4 are positioned above the blanking section 11 with the inclined bottom in the box body 1,

the secondary powder mixing device comprises a first box body 51, a second box body 61, an air driving device 52, a triangular baffle plate 62 and a pair of rollers 63,

the outlet of the first box body 51 and the second box body 61 are both provided with an inlet and an outlet, and the outlet of the first box body 51 is communicated with the inlet of the second box body 61,

the air-driving device 52 is provided in the first tank 51, to accomplish the scattering and mixing of the materials by the air-driving device 52,

a triangular baffle plate 62 is fixedly arranged below the inlet of the second box body 61,

a group of helical teeth are annularly arrayed on the outer wall of the roller, two ends of a pair of rollers 63 are respectively arranged in the second box body 61 through bearings, and the rollers 63 are respectively driven by a motor to oppositely drive, a mixture conveying area is formed between the rollers 63,

two blanking positions of the inclined surface of the triangular baffle plate 62 are both positioned above the pair of rollers 63,

the outlet center line of the mixture conveying area and the outlet center line of the second box body 61 are positioned on the same horizontal line.

The inlet of the first box body 51 is communicated with the bottom of the box body 1 through a discharge hole.

The outer layer of the box body 1 is provided with heat preservation cotton.

The first inverted V-shaped flow distribution plate 2, the second inverted V-shaped flow distribution plate 3 and the third inverted V-shaped flow distribution plate 4 are fixedly welded in the box body 1.

The outer layer of the box body 1 is provided with a steam heating sleeve.

A filter screen is arranged at the feed inlet at the top of the box body 1.

The end points at the corners of the first inverted V-shaped flow distribution plate 2 are positioned right below the center of the feed inlet at the top of the box body 1.

One inclined plate end point of the first inverted-V-shaped flow distribution plate 2 is positioned right above the corner end point of the second inverted-V-shaped flow distribution plate 3, and the other inclined plate end point of the first inverted-V-shaped flow distribution plate 2 is positioned right above the corner end point of the third inverted-V-shaped flow distribution plate 4.

The air-driving device 52 comprises a set of first air nozzles 53 arrayed at the bottom of the box body, and the air outlet of the first air nozzles 53 faces the feeding port of the first box body 51.

The air driving device 52 includes two sets of second air nozzles 54 disposed in the box body and arranged in a staggered manner, and the air outlet of the second air nozzle 54 is inclined downward.

The top end point of the triangular baffle plate 62 is positioned at the center of the inlet of the second box body 61.

Example 1: feeding a powdery raw material through a feeding hole at the top of a box body 1, adding waste heat gas in the process to a first inverted V-shaped flow distribution plate 2, a second inverted V-shaped flow distribution plate 3 and a third inverted V-shaped flow distribution plate 4 through a first air inlet 12, a second air inlet 13 and a third air inlet 14 respectively, heating the inverted V-shaped flow distribution plate by adding the waste heat gas when the powdery raw material enters the box body 1 and flows into the second inverted V-shaped flow distribution plate 3 and the third inverted V-shaped flow distribution plate 4 through inclined plates at two sides of the first inverted V-shaped flow distribution plate 2 respectively, heating the powdery raw material, finally flowing into an inlet of a first tank body 51 through a discharge hole at the bottom of the box body 1 through a blanking section 11 at the bottom of the box body 1, and scattering premixed powder in the first tank body for the second time through an air driving device 52 (the air driving device 52 mainly blows the powder which is not scattered completely in the premixing stage, and simultaneously, secondary mixing can be performed), the mixture material passing through the gas drive device 52 directly enters the upper part of the triangular baffle plate 62 through the outlet of the first tank body for shunting, and after shunting, the mixture material respectively enters the inclined teeth on the pair of rollers 63 of the second tank body 61, and enters the mixture conveying area between the pair of rollers 63 through the driving of the pair of rollers 63 and the inclined teeth (the pair of rollers 63 and the inclined teeth thereof are mainly designed to collide with each other when the pair of rollers 63 drive the material to pour the material into the mixture conveying area, so as to perform third mixing), and the mixture material output through the mixture conveying area directly enters subsequent processing.

Gas drive apparatus 52 example 1: when a group of first air nozzles 53 are arrayed at the bottom of the first box body 51, the outlets of the first air nozzles 53 face the first box body 51, agglomerated materials in the mixed materials entering the first box body 51 are scattered, all the mixed materials can be scattered, the mixed materials are converged at the outlets of the first box body 51 and then fall into the second box body 61.

Gas drive apparatus 52 example 2: when two sets of staggered second air nozzles 54 are arranged on the wall of the first box body 51, the materials enter the first box body 51, and are continuously blown to two sides of the inner wall of the first box body 51 through the two sets of staggered second air nozzles 54, and the mixture is blown downwards, so that the flow of the mixture is accelerated, the scattered materials can be played, and the material mixing effect can be also played.

The gas introduced into the gas drive 52 is dry hot gas.

The gas drive 52 is preferably fed with gas at 0.3-0.5 kpa.

And after the first-layer heating device and the second-layer heating device, three-layer heating devices to the Nth-layer heating device can be continuously added, wherein the number of the three-layer heating devices is from one, two, three, four to the Nth, and the like.

Claims (10)

1. A mixing system for a putty powder production line is characterized by comprising a preheating tank and a secondary powder mixing device,

the preheating tank comprises a tank body (1) and a shunt heating mechanism,

the top of the box body (1) is provided with a feed inlet,

a discharge hole is arranged at the bottom of the box body (1),

an inclined blanking section (11) is arranged at the bottom in the box body (1), the outlet of the blanking section (11) is communicated with the discharge hole at the bottom of the box body (1),

the shunt heating mechanism comprises a first layer heating device and a second layer heating device,

the one-layer heating device comprises a first inverted V-shaped flow distribution plate (2), a heating cavity is arranged in the first inverted V-shaped flow distribution plate (2), at least one first air inlet (12) and at least one first air outlet are formed in the box body (1), the first inverted V-shaped flow distribution plate (2) is arranged in the box body (1) and is positioned below a feed inlet at the top of the box body (1), the heating cavity in the first inverted V-shaped flow distribution plate (2) is communicated with the at least one first air inlet (12) and the at least one first air outlet on the box body (1),

the two-layer heating device comprises a second inverted V-shaped flow distribution plate (3) and a third inverted V-shaped flow distribution plate (4),

heating cavities are respectively arranged in the second inverted V-shaped flow distribution plate (3) and the third inverted V-shaped flow distribution plate (4), at least one second air inlet (13), at least one second air outlet, at least one third air inlet (14) and at least one third air outlet are arranged on the box body (1),

the second inverted V-shaped flow distribution plate (3) is arranged in the box body (1) and is positioned below one inclined plate end point of the first inverted V-shaped flow distribution plate (2), a heating cavity in the second inverted V-shaped flow distribution plate is communicated with at least one second air inlet (13) and at least one second air outlet on the box body (1),

a third inverted V-shaped flow distribution plate (4) is arranged in the box body (1) and is positioned below the end point of the other inclined plate of the first inverted V-shaped flow distribution plate (2), a heating cavity in the third inverted V-shaped flow distribution plate is communicated with at least one third air inlet (14) and at least one third air outlet on the box body (1),

the second inverted V-shaped flow distribution plate (3) and the third inverted V-shaped flow distribution plate (4) are positioned above the blanking section (11) with the bottom inclined in the box body (1),

the secondary powder mixing device comprises a first box body (51), a second box body (61), an air driving device (52), a triangular baffle plate (62) and a pair of rollers (63),

the outlet of the first box body (51) and the second box body (61) are both provided with an inlet and an outlet, the outlet of the first box body (51) is communicated with the inlet of the second box body (61),

the air driving device (52) is arranged in the first box body (51) to realize the scattering and mixing of the materials through the air driving device (52),

a triangular baffle plate (62) is fixedly arranged below the inlet of the second box body (61),

a group of helical teeth are annularly arrayed on the outer wall of the roller, two ends of a pair of rollers (63) are respectively arranged in the second box body (61) through bearings and respectively drive the pair of rollers (63) to oppositely drive through a motor, a mixture conveying area is formed between the pair of rollers (63),

two blanking parts of the inclined surface of the triangular baffle (62) are positioned above the pair of rollers (63),

the outlet center line of the mixture conveying area and the outlet center line of the second box body (61) are positioned on the same horizontal line,

the inlet of the first box body (51) is communicated with the discharge hole arranged at the bottom of the box body (1).

2. The mixing system for the putty powder production line is characterized in that heat preservation cotton is arranged on the outer layer of the box body (1).

3. The mixing system for the putty powder production line is characterized in that the first inverted V-shaped flow distribution plate (2), the second inverted V-shaped flow distribution plate (3) and the third inverted V-shaped flow distribution plate (4) are fixedly welded in the box body (1).

4. The mixing system for the putty powder production line is characterized in that a steam heating sleeve is arranged on the outer layer of the box body (1).

5. The mixing system for the putty powder production line as defined in claim 1, wherein a filter screen is arranged at a feed inlet at the top of the box body (1).

6. The mixing system for the putty powder production line as defined in claim 1, wherein the end points at the corners of the first inverted V-shaped splitter plate (2) are located right below the center of the feed inlet at the top of the box body (1).

7. A mixing system for putty powder production lines as defined in claim 1 wherein one of the sloping plate end points of the first inverted V-shaped splitter plate (2) is located directly above the corner end point of the second inverted V-shaped splitter plate (3) and the other sloping plate end point of the first inverted V-shaped splitter plate (2) is located directly above the corner end point of the third inverted V-shaped splitter plate (4).

8. The mixing system for the putty powder production line is characterized in that the air driving device (52) comprises a group of first air nozzles (53) arrayed at the bottom of the box body, and an air outlet of the first air nozzles (53) faces to an air inlet of the first box body (51).

9. The mixing system for the putty powder production line as claimed in claim 1, wherein the air driving device (52) comprises two sets of second air nozzles (54) arranged in the box body in a staggered manner, and an air outlet of the second air nozzles (54) is inclined downwards.

10. A mixing system for putty powder production lines as set forth in claim 1 characterised in that the top end of the triangular baffle plate (62) is located at the centre of the inlet of the second box (61).

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