CN217622054U - Anticorrosive pipe multilayer extruder - Google Patents

Abstract

The utility model discloses an anticorrosive pipe multilayer extruder belongs to anticorrosive pipe technical field, and its technical essential includes the base, anti-blocking mechanism is installed to the base top, anti-blocking mechanism includes electric putter, the electric putter top is connected with the motor, the power take off end fixedly connected with first rotation pole of motor, first rotation pole outer wall connection has first rotation area. The utility model discloses a drive the spiral rotor rod through electric putter and reciprocate, the motor drives first dwang and rotates, first dwang drives the second dwang through first rotating band and rotates, the second dwang rotates through the second and takes the third dwang to rotate, the third dwang drives the fourth dwang through the third rotating band and rotates, the second dwang, third dwang and fourth dwang drive the spiral rotor rod and rotate, the spiral rotor rod is rotated from top to bottom and is come to dredge to the material in the feeder hopper, avoid the material to lead to the fact the jam too much, and influence anticorrosive pipe production efficiency.

Description

Anticorrosive pipe multilayer extruder

Technical Field

The utility model belongs to the technical field of anticorrosive pipe, concretely relates to anticorrosive pipe multilayer extruder.

Background

The anti-corrosion pipe is also generally called as an anti-corrosion steel pipe, and refers to a steel pipe which is processed by an anti-corrosion process and can effectively prevent or slow down the corrosion phenomenon caused by chemical or electrochemical reaction in the transportation and use processes. According to the statistical data of China, the direct economic loss of steel pipe corrosion in China is 2800 billion each year, and the current global loss of steel pipe corrosion reaches $ 5000 billion each year. The corrosion-resistant pipe can effectively prevent or slow down corrosion.

The existing anticorrosive pipe is extruded and molded through an extruder, and in the feeding process, when materials are too much, the feeding hopper can be blocked, so that the production efficiency of the anticorrosive pipe is influenced.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an anticorrosive pipe multilayer extruder to solve the problem that proposes among the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: the on-line screen storage device comprises a base, anti-blocking mechanism is installed to the base top, anti-blocking mechanism includes electric putter, the electric putter top is connected with the motor, the first dwang of power take off end fixedly connected with of motor, first dwang outer wall connection has first rotating band, first rotating band inner wall connection has the second dwang, second dwang outer wall connection has the second rotating band, second rotating band inner wall connection has the third dwang, third dwang outer wall connection has the third rotating band, third rotating band inner wall connection has the fourth dwang, the second dwang the third dwang with the terminal equal fixedly connected with spiral shell rotary rod of fourth dwang, just electric putter end with the base top is connected.

Preferably, a heating mechanism is installed above the base and comprises an air heater, an air outlet of the air heater is connected with an air outlet pipe, an air guide pipe is connected to the outer wall of the air outlet pipe, and one end of the air guide pipe is connected with an annular heat conduction pipe.

Preferably, actuating mechanism is installed to the base top, actuating mechanism one side is connected with three group's barrels, three groups the barrel has connected gradually first extrusion mechanism, second extrusion mechanism and third extrusion mechanism.

Preferably, a feed hopper is connected to the upper part of the extrusion cylinder, a discharge pipe is connected to one end of the extrusion cylinder, and an extrusion head is connected to one side of the discharge pipe.

Preferably, the annular heat conduction pipe is wound on the outer wall of the extrusion cylinder.

Preferably, the outer walls of the first extrusion mechanism, the second extrusion mechanism and the third extrusion mechanism are provided with through holes matched with the air guide pipe, and one end of the air guide pipe penetrates through the through holes.

Preferably, the annular heat conduction pipe is made of copper and cooling liquid.

Compared with the prior art, the beneficial effects of the utility model are that:

1. the utility model discloses a power-driven push rod drives the spiral bull stick and reciprocates, the motor drives first dwang and rotates, first dwang drives the rotation of second dwang through first rotating band, the second dwang drives the rotation of third dwang through the second rotating band, the third dwang drives the rotation of fourth dwang through the third rotating band, second dwang, third dwang and fourth dwang drive the spiral bull stick and rotate, the spiral bull stick rotates from top to bottom to dredge the material in the feeder hopper, avoid the material to cause the jam too much, and influence anticorrosive pipe production efficiency;

2. the utility model discloses an air heater will be hot-blast carry out the tuber pipe on, go out the tuber pipe and will hot-blast carry the guide duct on, in the guide duct will hot-blast carry annular heat conduction pipe after that, hot-blastly flow along annular heat conduction pipe and carry out the even heating to the material, avoid the material to be heated inhomogeneous, take place not hot melt and influence the fashioned phenomenon of anticorrosive pipe.

Drawings

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

FIG. 2 is a schematic view of the spiral rotary rod structure of the present invention;

fig. 3 is the structural schematic diagram of the annular heat conducting pipe of the present invention.

In the figure: 1. a base; 2. a first extrusion mechanism; 3. a second extrusion mechanism; 4. a third extrusion mechanism; 5. a drive mechanism; 6. a feed hopper; 7. a heating mechanism; 701. a hot air blower; 702. an air outlet pipe; 703. an air guide pipe; 704. an annular heat conduction pipe; 8. an extrusion cylinder; 9. an anti-blocking mechanism; 901. an electric push rod; 902. a motor; 903. a first rotating lever; 904. a first rotating belt; 905. a second rotating lever; 906. a second rotating belt; 907. a third rotating rod; 908. a third rotating belt; 909. a fourth rotating rod; 910. a spiral rod; 10. a discharge pipe; 11. an extrusion head.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Please refer to fig. 1-3, the utility model provides an anticorrosive pipe multilayer extruder, which comprises a base 1, base 1 installs the top and prevents stifled mechanism 9, prevent stifled mechanism 9 and include electric putter 901, electric putter 901 top is connected with motor 902, the power take off end fixed connection of motor 902 has first dwang 903, first dwang 903 outer wall is connected with first rotating band 904, first rotating band 904 inner wall is connected with second dwang 905, second dwang 905 outer wall is connected with second rotating band 906, second rotating band 906 inner wall is connected with third dwang 907, third dwang 907 outer wall is connected with third rotating band 908, third rotating band 908 inner wall is connected with fourth dwang 909, second dwang 905, third dwang 907 and the terminal equal fixedly connected with spiral pole 910 of fourth dwang 909, and electric putter terminal is connected with base 1 top, it reciprocates to drive spiral pole through electric putter 901, motor 902 drives first dwang 903 and rotates, first dwang 903 drives second dwang 905 and rotates 905, second dwang 905 rotates through second dwang 906, it drives third dwang 910 and rotates to drive third dwang 910 and to drive the interior material rotation pole 907 to drive the spiral feeder hopper 910 and to rotate, it influences the production efficiency to dredge the third dwang 910 and to lead to the production spiral duct 909, the production spiral duct 907, the production efficiency is passed through third dwang 910, the third dwang 910, it rotates.

In this embodiment, preferably, a heating mechanism 7 is installed above the base 1, the heating mechanism 7 includes an air heater 701, an air outlet of the air heater 701 is connected with an air outlet pipe 702, an air guiding pipe 703 is connected to an outer wall of the air outlet pipe 702, one end of the air guiding pipe 703 is connected with an annular heat conducting pipe 704, hot air is conveyed to the air outlet pipe 702 through the air heater 701, the air outlet pipe 702 conveys the hot air to the air guiding pipe 703, then the air guiding pipe 703 conveys the hot air into the annular heat conducting pipe 704, the hot air flows along the annular heat conducting pipe 704 to uniformly heat the material, and the phenomenon that the material is heated unevenly and the formation of the anticorrosion pipe is affected due to non-hot melting is avoided.

In this embodiment, preferably, the driving mechanism 5 is installed above the base 1, three groups of extrusion cylinders 8 are connected to one side of the driving mechanism 5, and the three groups of extrusion cylinders 8 are sequentially connected to the first extrusion mechanism 2, the second extrusion mechanism 3 and the third extrusion mechanism 4.

In this embodiment, preferably, a feeding hopper 6 is connected to the upper portion of the extruding cylinder 8, a discharging pipe 10 is connected to one end of the extruding cylinder 8, and an extruding head 11 is connected to one side of the discharging pipe 10.

In this embodiment, preferably, the annular heat conducting pipe 704 is wound on the outer wall of the extrusion cylinder 8, so as to facilitate uniform heating of the material by hot air.

In this embodiment, preferably, through holes adapted to the air guide pipe 703 are formed in outer walls of the first extrusion mechanism 2, the second extrusion mechanism 3, and the third extrusion mechanism 4, and one end of the air guide pipe 703 penetrates through the through holes, so that the air guide pipe 703 can conveniently enter the first extrusion mechanism 2, the second extrusion mechanism 3, and the third extrusion mechanism 4.

In this embodiment, preferably, annular heat conducting pipe 704 is made of copper plus cooling fluid.

The utility model discloses a theory of operation and use flow: when the device is used, materials are firstly put into a feed hopper 6, then an electric push rod 901 drives a spiral rod 910 to move up and down, a motor 902 drives a first rotating rod 903 to rotate, the first rotating rod 903 drives a second rotating rod 905 to rotate through a first rotating belt 904, the second rotating rod 905 drives a third rotating rod 907 to rotate through a second rotating belt 906, the third rotating rod 907 drives a fourth rotating rod 909 to rotate through a third rotating belt 908, the second rotating rod 905, the third rotating rod 907 and the fourth rotating rod 909 drive the spiral rod 910 to rotate, the spiral rod 910 rotates up and down to dredge the materials in the feed hopper 6, the situation that the materials are too much to cause blockage and the production efficiency of an anti-corrosion pipe is affected is avoided, during production, hot air is firstly conveyed to an air outlet pipe 702 through a hot air blower 701, the hot air is conveyed to an air guide pipe 703, then the hot air is conveyed to an annular heat conduction pipe 704, the hot air flows along the annular heat conduction pipe 704 to uniformly heat the materials, and the phenomenon that the forming of the anti-corrosion pipe is affected due to non-uniform heating of the materials is avoided.

The electronic components and modules used in the utility model can be parts which are generally used in the current market and can realize the specific functions in the present case, and the specific model and the size can be selected and adjusted according to actual needs.

The foregoing illustrates and describes the general principles, features and advantages of the present invention. It should be understood by those skilled in the art that the present invention is not limited to the above embodiments, and the above embodiments and descriptions are only illustrative of the principles of the present invention, and that various changes and modifications may be made without departing from the spirit and scope of the present invention, and all such changes and modifications fall within the scope of the present invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (7)

1. The utility model provides an anticorrosive pipe multilayer extruder, includes base (1), its characterized in that: anti-blocking mechanism (9) is installed to base (1) top, anti-blocking mechanism (9) includes electric putter (901), electric putter (901) top is connected with motor (902), the power take off end fixedly connected with first dwang (903) of motor (902), first dwang (903) outer wall is connected with first rotation area (904), first rotation area (904) inner wall is connected with second dwang (905), second dwang (905) outer wall is connected with second rotation area (906), second rotation area (906) inner wall is connected with third dwang (907), third dwang (907) outer wall is connected with third rotation area (908), third rotation area (908) inner wall is connected with fourth dwang (909), second dwang (905), third dwang (907) and the equal fixedly connected with spiral shell rotary rod (910) in fourth dwang (909) end, just electric putter (901) end with base (1) top is connected.

2. The multi-layer extruder for corrosion-resistant pipes as claimed in claim 1, wherein: the heating mechanism (7) is installed above the base (1), the heating mechanism (7) comprises an air heater (701), an air outlet of the air heater (701) is connected with an air outlet pipe (702), the outer wall of the air outlet pipe (702) is connected with an air guide pipe (703), and one end of the air guide pipe (703) is connected with an annular heat conduction pipe (704).

3. A corrosion resistant pipe multi-layer extruder as claimed in claim 2, wherein: actuating mechanism (5) are installed to base (1) top, actuating mechanism (5) one side is connected with three groups and extrudes a section of thick bamboo (8), and is three groups it has first extrusion mechanism (2), second extrusion mechanism (3) and third extrusion mechanism (4) to extrude a section of thick bamboo (8) to connect gradually.

4. A corrosion resistant pipe multi-layer extruder as claimed in claim 3, wherein: extrude a section of thick bamboo (8) top and be connected with feeder hopper (6), it is connected with discharging pipe (10) to extrude a section of thick bamboo (8) one end, discharging pipe (10) one side is connected with extrudes head (11).

5. A corrosion resistant pipe multi-layer extruder as claimed in claim 3, wherein: the annular heat conducting pipe (704) is wound on the outer wall of the extrusion cylinder (8).

6. A corrosion resistant pipe multi-layer extruder as claimed in claim 3, wherein: the outer walls of the first extrusion mechanism (2), the second extrusion mechanism (3) and the third extrusion mechanism (4) are all provided with through holes matched with the air guide pipe (703), and one end of the air guide pipe (703) penetrates through the through holes.

7. A corrosion resistant pipe multi-layer extruder as claimed in claim 2, wherein: the annular heat conducting pipe (704) is made of copper plus cooling fluid.

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