CN212962852U - Cooling air pipe structure of high-efficiency cooling kiln - Google Patents

Abstract

The utility model provides a cooling air pipe structure of a high-efficiency cooling kiln, which comprises a ventilation pipe system and an auxiliary ventilation system arranged on the ventilation pipe system; through setting the ventilation pipe system to by ventilation pipe one, the ventilation pipe two, ventilation pipe three and ventilation pipe four, and set up supplementary ventilation system and can make ventilation pipe one, the ventilation pipe two, ventilation pipe three and ventilation pipe four all communicate with an solitary air intake, thereby the cooling of ventilating in its inside all directions, each face of material receives the cooling processing when more can than current unilateral ventilation structure, and ventilation pipe one, ventilation pipe two, ventilation pipe three and ventilation pipe four all have independent ventilation system can not appear being close to the air inlet department cooling effectual, keep away from the poor problem of air inlet department cooling effect.

Description

Cooling air pipe structure of high-efficiency cooling kiln

Technical Field

The utility model particularly relates to a high-efficient cooling kiln cooling tuber pipe structure.

Background

The design of the cooling section of the kiln is different in each factory, and the design requirements are as follows: the temperature of the material coming out of the high-temperature section of the kiln can be smoothly and stably reduced. The existing design can be selected from water cooling, air cooling and the like. If air cooling is used for cooling, the air cooling design mainly considered is as follows: how to make the air in the wind channel more even with each surface of material department of meeting each other thereby realize each surface evenly will cool down. Therefore, a new high-efficiency cooling air pipe structure of the cooling kiln is provided to achieve the purpose.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a high-efficient cooling kiln cooling tuber pipe structure to prior art not enough, this high-efficient cooling kiln cooling tuber pipe structure can solve above-mentioned problem well.

In order to meet the above requirements, the utility model adopts the following technical scheme: the cooling air pipe structure of the high-efficiency cooling kiln is provided and comprises an air pipe system and an auxiliary air system; the ventilation pipe system comprises a first ventilation pipe part, a second ventilation pipe part, a third ventilation pipe part and a fourth ventilation pipe part which are sequentially connected end to end, wherein the tops of the first ventilation pipe part, the second ventilation pipe part, the third ventilation pipe part and the fourth ventilation pipe part are respectively provided with a square air guide port, an annular limiting plate is arranged around the square air guide port, the front end of the square air guide port is provided with a first screw hole, and the inner side walls of the first ventilation pipe part, the second ventilation pipe part, the third ventilation pipe part and the fourth ventilation pipe part are uniformly provided with ventilation openings; supplementary ventilation system including be used for in proper order with fourth auxiliary air pipe, third auxiliary air pipe, the supplementary tuber pipe of second and the first auxiliary air pipe of ventilation pipe four parts intercommunication, fourth auxiliary air pipe, the supplementary tuber pipe of third, the supplementary tuber pipe of second and the front end bottom of first auxiliary air pipe all are equipped with preceding spacing piece, be equipped with the second screw on the preceding spacing piece, the bottom of fourth auxiliary air pipe, the supplementary tuber pipe of third, the supplementary tuber pipe of second and first auxiliary air pipe all is equipped with the spacing piece of L shape.

The cooling air pipe structure of the high-efficiency cooling kiln has the advantages that:

through setting the ventilation pipe system to by ventilation pipe one, the ventilation pipe two, ventilation pipe three and ventilation pipe four, and set up supplementary ventilation system and can make ventilation pipe one, the ventilation pipe two, ventilation pipe three and ventilation pipe four all communicate with an solitary air intake, thereby the cooling of ventilating in its inside all directions, each face of material receives the cooling processing when more can than current unilateral ventilation structure, and ventilation pipe one, ventilation pipe two, ventilation pipe three and ventilation pipe four all have independent ventilation system can not appear being close to the air inlet department cooling effectual, keep away from the poor problem of air inlet department cooling effect.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the application and together with the description serve to explain the application and not to limit the application. In the drawings:

fig. 1 schematically shows a structural schematic diagram of a cooling air duct structure of an efficient cooling kiln according to an embodiment of the present application.

Fig. 2 schematically shows a schematic structural diagram of four ventilation pipes of a cooling air pipe structure of an efficient cooling kiln according to one embodiment of the application.

Fig. 3 schematically shows a structural diagram of a first auxiliary air duct of the cooling air duct structure of the high-efficiency cooling kiln according to an embodiment of the present application.

Fig. 4 schematically shows a cross-sectional view of four ventilation pipes of a cooling air pipe structure of an efficient cooling kiln according to one embodiment of the application.

Wherein: 1. a ventilation pipe system; 2. an auxiliary ventilation system; 3. a connecting strip; 4. a handle; 5. a first auxiliary air duct; 6. a second auxiliary air duct; 7. a third auxiliary air duct; 8. a fourth auxiliary air duct; 9. a first vent pipe; 10. a second ventilation pipe part; 11. a third ventilation pipe; 12. four parts of ventilation pipe; 13. a first concave limiting buckle; 14. a second concave limiting buckle; 15. a third concave limiting buckle; 16. a magnet block; 17. a magnet piece; 18. a vent; 19. a square air guide port; 20. an annular limiting plate; 21. a first screw hole; 22. an L-shaped limiting sheet; 23. a front limiting sheet; 24. a second screw hole; 25. a hollow cavity; 26. an auxiliary tube fixing member.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application will be described in further detail with reference to the accompanying drawings and specific embodiments.

In the following description, references to "one embodiment," "an embodiment," "one example," "an example," etc., indicate that the embodiment or example so described may include a particular feature, structure, characteristic, property, element, or limitation, but every embodiment or example does not necessarily include the particular feature, structure, characteristic, property, element, or limitation. Moreover, repeated use of the phrase "in accordance with an embodiment of the present application" although it may possibly refer to the same embodiment, does not necessarily refer to the same embodiment.

Certain features that are well known to those skilled in the art have been omitted from the following description for the sake of simplicity.

According to an embodiment of the present application, a cooling air duct structure of an efficient cooling kiln is provided, as shown in fig. 1-4, which includes an air duct system 1 and an auxiliary air duct system 2; the ventilation pipe system 1 comprises a first ventilation pipe part 9, a second ventilation pipe part 10, a third ventilation pipe part 11 and a fourth ventilation pipe part 12 which are sequentially connected end to end, the tops of the first ventilation pipe part 9, the second ventilation pipe part 10, the third ventilation pipe part 11 and the fourth ventilation pipe part 12 are respectively provided with a square air guide opening 19, an annular limiting plate 20 is arranged around the square air guide opening 19, the front end of the square air guide opening 19 is provided with a first screw hole 21, and the inner side walls of the first ventilation pipe part 9, the second ventilation pipe part 10, the third ventilation pipe part 11 and the fourth ventilation pipe part 12 are uniformly provided with ventilation openings 18; supplementary ventilation system 2 including be used for in proper order with fourth auxiliary air pipe 8, third auxiliary air pipe 7, the supplementary tuber pipe 6 of second and the first auxiliary air pipe 5 of first 9, the second 10 of ventilation pipe, the three 11 and the 12 intercommunication of ventilation pipe four parts, the front end bottom of fourth auxiliary air pipe 8, the supplementary tuber pipe 7 of third, the supplementary tuber pipe 6 of second and first auxiliary air pipe 5 all is equipped with preceding spacing piece 23, be equipped with second screw 24 on the preceding spacing piece 23, the bottom of fourth auxiliary air pipe 8, the supplementary tuber pipe 7 of third, the supplementary tuber pipe 6 of second and first auxiliary air pipe 5 all is equipped with the spacing piece 22 of L shape.

According to an embodiment of the application, the hollow cavities 25 are arranged in the side walls of the first ventilating pipe part 9, the second ventilating pipe part 10, the third ventilating pipe part 11 and the fourth ventilating pipe part 12 of the high-efficiency cooling kiln cooling air pipe structure, and the hollow cavities 25 are communicated with the ventilating openings 18 and the square air guide openings 19.

According to an embodiment of the application, the openings are arranged at the bottoms of the front ends of the fourth auxiliary air pipe 8, the third auxiliary air pipe 7, the second auxiliary air pipe 6 and the first auxiliary air pipe 5 of the cooling air pipe structure of the high-efficiency cooling kiln.

According to an embodiment of the application, this high-efficient cooling kiln cooling tuber pipe structure is still including setting up auxiliary tube fixed part 26 above supplementary ventilation system 2, auxiliary tube fixed part 26 includes first spill stop collar 13, second spill stop collar 14 and third spill stop collar 15, all connect through connecting strip 3 between first spill stop collar 13 and the second spill stop collar 14 and between second spill stop collar 14 and the third spill stop collar 15

According to one embodiment of the application, a handle 4 is arranged on the top of the connecting strip 3 of the cooling air pipe structure of the high-efficiency cooling kiln.

According to an embodiment of the application, the first auxiliary air pipe 5, the second auxiliary air pipe 6, the third auxiliary air pipe 7 and the fourth auxiliary air pipe 8 of the high-efficiency cooling kiln cooling air pipe structure are square pipes with the outer diameters of five centimeters, the width of the inner end face of the third concave limiting buckle 15 is ten centimeters, the width of the inner end face of the second concave limiting buckle 14 is fifteen centimeters, and the width of the inner end face of the first concave limiting buckle 13 is twenty centimeters.

According to an embodiment of the application, the bottom of the end surfaces of the two sides of the first concave limiting buckle 13, the second concave limiting buckle 14 and the third concave limiting buckle 15 of the cooling air pipe structure of the high-efficiency cooling kiln are respectively provided with a magnet block 16, and the upper end surfaces of the first ventilation pipe part 9, the second ventilation pipe part 10, the third ventilation pipe part 11 and the fourth ventilation pipe part 12 are respectively provided with a magnet piece 17.

According to an embodiment of the application, when the high-efficiency cooling kiln cooling air pipe structure is used, the ventilation pipe system 1 and the auxiliary ventilation system 2 can be communicated with the output end of the fan, meanwhile, the ventilation pipe system 1, the first auxiliary air pipe 5, the second auxiliary air pipe 6, the third auxiliary air pipe 7 and the fourth auxiliary air pipe 8 can be blown, the air entering the first auxiliary air pipe 5, the second auxiliary air pipe 6, the third auxiliary air pipe 7 and the fourth auxiliary air pipe 8 can respectively enter the ventilation pipe four part 12, the ventilation pipe three part 11, the ventilation pipe two part 10 and the ventilation pipe one part 9, and is discharged from the ventilation openings 18 inside the ventilation pipe four part 12, the ventilation pipe three part 11, the ventilation pipe two part 10 and the ventilation pipe one part 9, so that ventilation from all directions of materials can be realized.

According to an embodiment of the application, as shown in fig. 2 to 3, the auxiliary ventilation system 2 and the ventilation pipe system 1 of the high-efficiency cooling kiln cooling air pipe structure are independently arranged, when the assembly is performed, the first auxiliary air pipe 5, the second auxiliary air pipe 6, the front limiting sheet 23 at the front end of the third auxiliary air pipe 7 and the front end of the fourth auxiliary air pipe 8 are inserted into the corresponding square air guide port 19, then the first auxiliary air pipe 5, the second auxiliary air pipe 6, the third auxiliary air pipe 7 and the fourth auxiliary air pipe 8 are pulled backwards to enable the bottom of the L-shaped limiting sheet 22 to be clamped inside the annular limiting plate 20, at the moment, the first screw hole 21 coincides with the second screw hole 24, and the fixing can be performed by inserting a bolt.

According to an embodiment of the present application, after the structure of the ventilation pipe system 1 and the auxiliary ventilation system 2 is fixed, the auxiliary pipe fixing member 26 may be placed on the top of the auxiliary ventilation system 2, as shown in fig. 1, the first concave position-limiting buckle 13 is clamped above the first auxiliary air pipe 5, the second auxiliary air pipe 6, the third auxiliary air pipe 7 and the fourth auxiliary air pipe 8, the second concave position-limiting buckle 14 is clamped on the upper portions of the first auxiliary air pipe 5, the second auxiliary air pipe 6 and the third auxiliary air pipe 7, the third concave position-limiting buckle 15 is clamped on the upper portions of the first auxiliary air pipe 5 and the second auxiliary air pipe 6, and the magnet blocks 16 at the bottoms of the first concave position-limiting buckle 13, the second concave position-limiting buckle 14 and the third concave position-limiting buckle 15 are adsorbed on the magnet sheets 17 for fixing.

According to an embodiment of the present application, the bottoms of the front ends of the first auxiliary air duct 5, the second auxiliary air duct 6, the third auxiliary air duct 7 and the fourth auxiliary air duct 8 may be provided with square openings, so that the first auxiliary air duct 5, the second auxiliary air duct 6, the third auxiliary air duct 7 and the fourth auxiliary air duct 8 may be communicated with the fourth air duct part 12, the third ventilation duct part 11, the second ventilation duct part 10 and the first ventilation duct part 9 through the square air guide openings 19; the four parts 12, the three parts 11, the two parts 10 and the one part 9 of the ventilation pipe are connected end to end in sequence and can be of an integrally formed structure.

According to an embodiment of the application, this high-efficient cooling kiln cooling air pipe structure is through setting up ventilation pipe system 1 to by ventilation pipe one 9, ventilation pipe two 10, ventilation pipe three 11 and ventilation pipe four 12, and set up auxiliary ventilation system 2 and can make ventilation pipe one 9, ventilation pipe two 10, ventilation pipe three 11 and ventilation pipe four 12 all communicate with an solitary air intake, thereby the cooling of ventilating is carried out in its each direction, each face of material receives the cooling when current unilateral ventilation structure more can be handled, and ventilation pipe one 9, ventilation pipe two 10, ventilation pipe three 11 and ventilation pipe four 12 all have independent ventilation system can not appear being close to the good effect of air inlet department cooling, keep away from the poor problem of air inlet department cooling effect.

The above-described embodiments are merely illustrative of several embodiments of the present invention, which are described in detail and detail, but should not be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the claims.

Claims (3)

1. The utility model provides a high-efficient cooling kiln cooling tuber pipe structure which characterized in that: comprises an air ventilation system and an auxiliary ventilation system;

the ventilation pipe system comprises a first ventilation pipe part, a second ventilation pipe part, a third ventilation pipe part and a fourth ventilation pipe part which are sequentially connected end to end, wherein the tops of the first ventilation pipe part, the second ventilation pipe part, the third ventilation pipe part and the fourth ventilation pipe part are respectively provided with a square air guide port, an annular limiting plate is arranged around the square air guide port, the front end of the square air guide port is provided with a first screw hole, and the inner side walls of the first ventilation pipe part, the second ventilation pipe part, the third ventilation pipe part and the fourth ventilation pipe part are uniformly provided with ventilation openings;

supplementary ventilation system including be used for in proper order with fourth auxiliary air pipe, third auxiliary air pipe, the supplementary tuber pipe of second and the first auxiliary air pipe of ventilation pipe four parts intercommunication, fourth auxiliary air pipe, the supplementary tuber pipe of third, the supplementary tuber pipe of second and the first auxiliary air pipe's of fourth auxiliary air pipe, third auxiliary air pipe, the supplementary tuber pipe of second and front end bottom all is equipped with preceding spacing piece, be equipped with the second screw on the preceding spacing piece, the bottom of the supplementary tuber pipe of fourth, third auxiliary air pipe, the supplementary tuber pipe of second and first auxiliary air pipe all is equipped with the spacing piece of L shape.

2. The cooling air duct structure of the high-efficiency cooling kiln of claim 1, which is characterized in that: and hollow cavities are arranged in the side walls of the first ventilation pipe part, the second ventilation pipe part, the third ventilation pipe part and the fourth ventilation pipe part, and are communicated with the ventilation openings and the square air guide openings.

3. The cooling air duct structure of the high-efficiency cooling kiln of claim 1, which is characterized in that: and openings are formed in the bottoms of the front ends of the fourth auxiliary air pipe, the third auxiliary air pipe, the second auxiliary air pipe and the first auxiliary air pipe.

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