CN220717230U

CN220717230U - Cooling type plate production system

Info

Publication number: CN220717230U
Application number: CN202322471084.4U
Authority: CN
Inventors: 韩文; 曹建宁; 伏彬
Original assignee: MCC Capital Engineering and Research Incorporation Ltd; CERI Technology Co Ltd
Current assignee: MCC Capital Engineering and Research Incorporation Ltd; CERI Technology Co Ltd
Priority date: 2023-09-12
Filing date: 2023-09-12
Publication date: 2024-04-05
Anticipated expiration: 2033-09-12

Abstract

The utility model provides a cooling type plate production system, which relates to the technical field of plate production equipment and comprises a main rolling line, a first conveying line, a first shearing line, a first cooling bed mechanism, a second conveying line and a second shearing line, wherein the main rolling line is provided with the first cooling mechanism, the first conveying line is connected with an outlet of the main rolling line, the outlet of the first conveying line is provided with the second cooling mechanism, the first shearing line is connected with an outlet of the first conveying line, and an inlet and an outlet of the first cooling bed mechanism are sequentially connected with the first conveying line; the inlet of the second cooling bed mechanism is connected with the first conveying line, the second conveying line is arranged side by side with the first conveying line, the second conveying line is connected with the outlet of the second cooling bed mechanism, and the outlet of the second conveying line is provided with a third cooling mechanism; the inlet of the second shear line is connected with the outlet of the second conveying line. According to the utility model, the cooling efficiency of the two production paths can be differentially set, so that the cooling requirements of plates with different thicknesses are met.

Description

Cooling type plate production system

Technical Field

The utility model relates to the technical field of plate production equipment, in particular to a cooling type plate production system.

Background

Before cutting the rolled plate, the temperature of the plate needs to be reduced, so that the influence on the cutting quality of the plate due to the overhigh temperature of the plate is avoided. In the prior art, the rolled plate is generally conveyed to a cooling bed for cooling, and the cooling bed is generally cooled by adopting an air heat exchange mode, so that the cooling efficiency is lower. When the thickness of panel is great or the output of production line is higher, the cooling efficiency of cooling bed is difficult to satisfy the cooling needs of panel, leads to still having higher temperature on the panel. In order to avoid influencing the shearing quality of the plates, the plates with too high temperature can be gradually piled up on the cooling bed to further cool down, so that the production efficiency of the production line is reduced.

Disclosure of Invention

In order to overcome the above-mentioned drawbacks of the prior art, the technical problem to be solved by the embodiments of the present utility model is to provide a cooling type board production system for improving the cooling efficiency in the board production process.

The above object of the present utility model can be achieved by the following technical scheme, and the present utility model provides a cooling type board production system, comprising:

the main rolling line is provided with a rolling mechanism and a first cooling mechanism;

the first conveying line is connected with the outlet of the main rolling line, and a second cooling mechanism is arranged at the outlet of the first conveying line;

the first shearing line is connected with the outlet of the first conveying line, and a first shearing mechanism is arranged on the first shearing line;

the first cooling bed mechanism is arranged on one side of the first conveying line, and an inlet of the first cooling bed mechanism and an outlet of the first cooling bed mechanism are sequentially connected with the first conveying line along the conveying direction of the first conveying line;

the second cooling bed mechanism is arranged on the other side of the first conveying line, and an inlet of the second cooling bed mechanism is connected with the first conveying line along the conveying direction of the first conveying line and is arranged between the inlet of the first cooling bed mechanism and the outlet of the first cooling bed mechanism;

the second conveying line is arranged side by side with the first conveying line, the second conveying line is connected with the outlet of the second cooling bed mechanism, and the outlet of the second conveying line is provided with a third cooling mechanism;

and the inlet of the second shearing line is connected with the outlet of the second conveying line, and a second shearing mechanism is arranged on the second shearing line.

In a preferred embodiment of the present utility model, the second cooling mechanism includes a plurality of second cooling nozzles, and a second conveying pipeline communicating with each of the second cooling nozzles, the plurality of second cooling nozzles are arranged at intervals on the upper side and the lower side of the first conveying line, and the second conveying pipeline is capable of controllably inputting a cooling medium into each of the second cooling nozzles.

In a preferred embodiment of the present utility model, the third cooling mechanism includes a plurality of third cooling nozzles, and third conveying pipes communicating with each of the third cooling nozzles, the plurality of third cooling nozzles being arranged at intervals on both upper and lower sides of the second conveying line, the third conveying pipes being capable of controllably inputting a cooling medium into each of the third cooling nozzles.

In a preferred embodiment of the present utility model, the number of the third cooling nozzles is smaller than the number of the second cooling nozzles.

In a preferred embodiment of the present utility model, the rolling mechanism includes a roughing mill and a finishing mill disposed in sequence on the main rolling line, and the first cooling mechanism is disposed on the main rolling line downstream of the finishing mill.

In a preferred embodiment of the present utility model, the rolling mechanism further includes a pre-straightener and a hot straightener disposed in this order on the main rolling line, the pre-straightener being disposed downstream of the finishing mill, and the first cooling mechanism being disposed between the pre-straightener and the hot straightener.

In a preferred embodiment of the present utility model, the first cooling mechanism includes a plurality of first cooling nozzles, and a first conveying pipeline communicating with each of the first cooling nozzles, the plurality of first cooling nozzles are arranged at intervals on the upper side and the lower side of the main rolling line, and the first conveying pipeline is capable of controllably inputting a cooling medium into each of the first cooling nozzles.

In a preferred embodiment of the present utility model, the first cooling bed mechanism includes a first cooling bed, a second cooling bed, and a first cooling bed roller way, and along a conveying direction of the first conveying line, the first cooling bed and the second cooling bed are sequentially connected to the first conveying line, and the first cooling bed and the second cooling bed are connected through the first cooling bed roller way.

In a preferred embodiment of the present utility model, the second cooling bed mechanism includes a third cooling bed, and the third cooling bed connects the first conveyor line and the second conveyor line.

In a preferred embodiment of the present utility model, the second cooling bed mechanism further includes a fourth cooling bed and a second cooling bed roller table, the fourth cooling bed is connected to the outlet of the third cooling bed through the second cooling bed roller table, and the outlet of the fourth cooling bed is connected to the second conveying line.

The technical scheme of the utility model has the following remarkable beneficial effects:

when the cooling type plate production system is used, the plate can be conveyed along the main rolling line, the plate can be rolled and straightened through the rolling mechanism, and the plate can be subjected to primary cooling through the first cooling mechanism, so that the temperature of the plate when the plate is input into the first conveying line is reduced, and the heat of the high-temperature plate is prevented from being transmitted to the first conveying line to reduce the service life of the first conveying line.

Further, the first cooling bed mechanism arranged on one side of the first conveying line can be used for carrying out secondary cooling on the plate, so that the temperature of the plate is further reduced. When the temperature of the plate still exceeds the target temperature after passing through the first cooling bed mechanism, the plate can be subjected to three-stage cooling through the second cooling mechanism arranged at the outlet of the first conveying line, so that the temperature of the plate is reduced again, and then the cooled plate can be input into the first shearing line for shearing operation.

According to the utility model, the temperature on the plate is obviously reduced by carrying out three cooling treatments on the plate, the influence on the shearing quality caused by the input of the high-temperature plate into the first shearing line is avoided, the high-temperature conduction of the plate to the shearing mechanism is also avoided by controlling the temperature of the plate, and the service life of the shearing mechanism is prolonged. According to the utility model, a production path is formed by the first conveying line, the first cooling bed mechanism and the first shearing line, a second production path is formed by the second cooling bed mechanism, the second conveying line and the second shearing line, and a one-machine two-flow arrangement mode can be formed by the two production paths, so that a more flexible production arranging and braiding mode is realized. And through setting up the cooling efficiency of two production routes differently, can satisfy the cooling needs of different thickness planks.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings required for the description of the embodiments will be briefly described below, and it is apparent that the drawings in the following description are only some embodiments of the present utility model, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

The drawings described herein are for illustration purposes only and are not intended to limit the scope of the present disclosure in any way. In addition, the shapes, proportional sizes, and the like of the respective components in the drawings are merely illustrative for aiding in understanding the present utility model, and are not particularly limited. Those skilled in the art with access to the teachings of the present utility model can select a variety of possible shapes and scale sizes to practice the present utility model as the case may be.

Fig. 1 is a schematic structural view of a cooling type board production system according to the present utility model.

Reference numerals of the above drawings:

1. a main rolling line; 11. a first cooling mechanism; 12. a roughing mill; 13. finishing mill; 14. a pre-straightener; 15. a thermal straightener;

2. a first conveyor line; 21. a second cooling mechanism;

3. a first shear line;

4. a first cooling bed mechanism; 41. a first cooling bed; 42. a second cooling bed; 43. a first cooling bed roller way;

5. a second cooling bed mechanism; 51. a third cooling bed; 52. a fourth cooling bed; 53. a second cooling bed roller way;

6. a second conveyor line; 61. a third cooling mechanism;

7. and a second shear line.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1 in combination, a cooling type sheet material production system is provided in an embodiment of the present utility model, and the cooling type sheet material production system includes a main rolling line 1, a first conveying line 2, a first cutting line 3, a first cooling bed mechanism 4, a second cooling bed mechanism 5, a second conveying line 6, and a second cutting line 7, where the main rolling line 1 is provided with a rolling mechanism and a first cooling mechanism 11; the first conveying line 2 is connected with the outlet of the main rolling line 1, and a second cooling mechanism 21 is arranged at the outlet of the first conveying line 2; the first shearing line 3 is connected with the outlet of the first conveying line 2, and a first shearing mechanism is arranged on the first shearing line 3; the first cooling bed mechanism 4 is arranged at one side of the first conveying line 2, and an inlet of the first cooling bed mechanism 4 and an outlet of the first cooling bed mechanism 4 are sequentially connected with the first conveying line 2 along the conveying direction of the first conveying line 2; the second cooling bed mechanism 5 is arranged on the other side of the first conveying line 2, and an inlet of the second cooling bed mechanism 5 is connected with the first conveying line 2 along the conveying direction of the first conveying line 2 and is arranged between an inlet of the first cooling bed mechanism 4 and an outlet of the first cooling bed mechanism 4; a second conveying line 6 is arranged side by side with the first conveying line 2, the second conveying line 6 is connected with the outlet of the second cooling bed mechanism 5, and a third cooling mechanism 61 is arranged at the outlet of the second conveying line 6; the inlet of the second shearing line 7 is connected with the outlet of the second conveying line 6, and a second shearing mechanism is arranged on the second shearing line 7.

In the whole, when this cooled panel production system used, the panel can be carried along main rolling line 1, can roll and straighten the processing to the panel through rolling mechanism to can carry out one-level cooling to the panel through first cooling mechanism 11, thereby reduced the temperature when panel input first transfer chain 2, avoid the heat conduction of high temperature panel to first transfer chain 2 and reduce first transfer chain 2's life.

Further, the sheet material can be subjected to secondary cooling by the first cooling bed mechanism 4 provided at one side of the first conveying line 2, thereby further reducing the temperature of the sheet material. When the temperature of the plate still exceeds the target temperature after passing through the first cooling bed mechanism 4, the plate can be subjected to three-stage cooling through the second cooling mechanism 21 arranged at the outlet of the first conveying line 2, so that the temperature of the plate is reduced again, and then the cooled plate can be input into the first shearing line 3 for shearing operation.

According to the utility model, the temperature on the plate is obviously reduced by carrying out three cooling treatments on the plate, the influence on the shearing quality caused by the input of the high-temperature plate into the first shearing line 3 is avoided, the high-temperature conduction of the plate to the shearing mechanism is also avoided by controlling the temperature of the plate, and the service life of the shearing mechanism is prolonged.

In the utility model, a production path is formed by the first conveying line 2, the first cooling bed mechanism 4 and the first shearing line 3, a second production path is formed by the second cooling bed mechanism 5, the second conveying line 6 and the second shearing line 7, and a one-machine two-stream arrangement mode can be formed by the two production paths, so that the utility model has a more flexible production arranging mode. And through setting up the cooling efficiency of two production routes differently, can satisfy the cooling needs of different thickness planks.

The plate is a steel plate with the thickness of 4.5mm to 25.0mm, and the production line can be applied to steel plates with other thicknesses. The main rolling line 1, the first conveyor line 2, the first shear line 3, the second conveyor line 6 and the second shear line 7 may be provided as roller tables through which the sheet material is conveyed.

In the embodiment of the present utility model, the second cooling mechanism 21 includes a plurality of second cooling nozzles (not shown) arranged at intervals on both upper and lower sides of the first conveying line 2, and a second conveying line (not shown) communicating with each of the second cooling nozzles, the second conveying line being capable of controllably inputting a cooling medium into each of the second cooling nozzles.

Specifically, a plurality of second cooling nozzles are arranged at intervals and are laid on the upper and lower sides of the partial second conveyor line 6. The designer may adjust the arrangement of the second cooling nozzles according to the cooling requirement, for example, the second cooling nozzles may be arranged in an array, which is not particularly limited herein.

The cooling medium can be input into each second cooling nozzle through the second conveying pipeline, so that each second cooling nozzle uniformly sprays the cooling medium onto the end surfaces of the two sides of the plate, and the effect of uniform cooling is achieved.

Wherein, can set up pump group and control valve on the second delivery line to can control the delivery volume of coolant medium through control pump group and control valve. The designer can determine the kind of the cooling medium, such as cooling water or gas, according to the cooling requirement, without being particularly limited herein.

In the embodiment of the present utility model, the third cooling mechanism 61 includes a plurality of third cooling nozzles (not shown) arranged at intervals on both upper and lower sides of the second conveying line 6, and a third conveying line (not shown) communicating with each of the third cooling nozzles, the third conveying line being capable of controllably inputting a cooling medium into each of the third cooling nozzles.

Specifically, a plurality of second cooling nozzles are arranged at intervals and are paved on the upper side and the lower side of a part of the third conveying line. The designer may adjust the arrangement of the third cooling nozzles according to the cooling requirement, for example, the third cooling nozzles may be arranged in an array, which is not particularly limited herein.

The cooling medium can be input into each third cooling nozzle through the third conveying pipeline, so that each third cooling nozzle uniformly sprays the cooling medium onto the end surfaces of the two sides of the plate, and the effect of uniform cooling is achieved.

Wherein, pump group and control valve can be set up on the third delivery line to can control the delivery volume of coolant through control pump group and control valve. The designer can determine the kind of the cooling medium, such as cooling water or gas, according to the cooling requirement, without being particularly limited herein.

Further, the number of the third cooling nozzles is smaller than the number of the second cooling nozzles. For example, in the case where the cooling efficiencies of the first cooling bed mechanism 4 and the second cooling bed mechanism 5 are identical, the cooling efficiencies of the two production paths can be set differently by making the number of the third cooling nozzles smaller than the number of the second cooling nozzles, and the cooling needs of the plates of different thicknesses can be satisfied.

The second cooling nozzles of the second cooling mechanism 21 are more in number, have higher cooling efficiency, and are suitable for cooling plates with larger thickness. And the third cooling mechanism 61 is provided with a smaller number of third cooling nozzles, and has a lower cooling efficiency than the second cooling mechanism 21, and is suitable for cooling a plate material having a smaller thickness.

Of course, in the actual use process, the plate with smaller thickness can also be directly input into the first conveying line 2 along the main rolling line 1, and is input into the first shear line 3 after being cooled once by the second cooling mechanism 21, and the first cooling bed mechanism 4 is not needed, so that the production efficiency of the plate is improved.

In an embodiment of the utility model, the rolling mechanism comprises a roughing mill 12 and a finishing mill 13 arranged in sequence on the main line 1, the first cooling mechanism 11 being arranged on the main line 1 downstream of the finishing mill 13.

The roughing operation can be performed on the plate by the roughing mill 12, and the finishing operation can be performed on the roughed plate by the finishing mill 13, thereby rolling the plate to a target thickness. The specific configurations of the roughing mill 12 and finishing mill 13 can be determined by the designer according to the rolling requirements, and are not particularly limited herein.

In the embodiment of the present utility model, the rolling mechanism further includes a pre-straightener 14 and a hot straightener 15 which are sequentially provided on the main rolling line 1, the pre-straightener 14 is provided downstream of the finishing mill 13, and the first cooling mechanism 11 is provided between the pre-straightener 14 and the hot straightener 15.

By the cooperation of the pre-straightener 14 and the hot straightener 15, the rolled sheet can be straightened, thereby improving the processing quality of the sheet. The specific configurations of the pre-straightener 14 and the thermal straightener 15 can be determined by the designer according to the straightening requirements, and are not particularly limited herein.

In the embodiment of the present utility model, the first cooling mechanism 11 includes a plurality of first cooling nozzles (not shown) arranged at intervals on both upper and lower sides of the main rolling line 1, and a first conveying line (not shown) communicating with each of the first cooling nozzles, the first conveying line being capable of controllably inputting a cooling medium into each of the first cooling nozzles.

Specifically, a plurality of first cooling nozzles are arranged at intervals and are laid on the upper and lower sides of a part of the main rolling line 1. The designer may adjust the arrangement of the first cooling nozzles according to the cooling requirement, for example, the first cooling nozzles may be arranged in an array, which is not limited herein.

The cooling medium can be input into each first cooling nozzle through the first conveying pipeline, so that each first cooling nozzle uniformly sprays the cooling medium onto the end surfaces of the two sides of the plate, and the effect of uniform cooling is achieved.

In the embodiment of the present utility model, the first cooling bed mechanism 4 includes a first cooling bed 41, a second cooling bed 42, and a first cooling bed roller table 43, the first cooling bed 41 and the second cooling bed 42 are sequentially connected to the first conveyor line 2 along the conveying direction of the first conveyor line 2, and the first cooling bed 41 and the second cooling bed 42 are connected to each other through the first cooling bed roller table 43.

Specifically, the first cooling bed 41 and the second cooling bed 42 are disposed on the same side of the first conveying line 2, and the conveying direction of the first cooling bed 41 and the conveying direction of the second cooling bed 42 may be perpendicular to the conveying direction of the first conveying line 2.

The plates can be air-cooled through the first cooling bed 41 and the second cooling bed 42, so that a cooling mode is increased, and the cooling requirements of different plates can be met. In addition, by matching the first cooling bed 41 and the second cooling bed 42 with the second cooling mechanism 21, the cooling paths of the plates can be configured differently according to the cooling requirements of different plates, so that the plates can be cooled only by the first cooling bed 41 and the second cooling bed 42, or the plates can also be cooled by the first cooling bed 41, the second cooling bed 42 and the second cooling mechanism 21, and the cooling flexibility is better.

The temperature sensor can be used for detecting the temperature of the plates in the conveying process, so that the temperature information of each plate can be conveniently obtained, and the cooling mode of each plate can be better controlled.

In the embodiment of the present utility model, the second cooling bed mechanism 5 includes a third cooling bed 51, and the third cooling bed 51 connects the first conveyor line 2 and the second conveyor line 6.

In a specific embodiment, the third cooling bed 51 is disposed on the other side of the first cooling roller table with respect to the first cooling bed 41 and the second cooling bed 42.

By arranging the third cooling bed 51 and connecting the third cooling bed 51 with the second cutting line 7, the first cutting line 3 and the second cutting line 7 respectively form two parallel production paths, and the two paths can cool and cut the plate. In the actual working process, the transportation path of the plate can be selected according to the temperature of the plate to be sheared and the shearing requirement, so that the situation that the transportation path of the plate with high temperature in large batches is the same to cause congestion is effectively avoided, the flexibility of production organization is improved, the probability of bottleneck formation of a production line is reduced, and the production efficiency is improved.

In a specific embodiment, the second cooling bed mechanism 5 further includes a fourth cooling bed 52 and a second cooling bed roller way 53, the fourth cooling bed 52 is connected to the outlet of the third cooling bed 51 through the second cooling bed roller way 53, and the outlet of the fourth cooling bed 52 is connected to the second conveying line 6. The third cooling bed 51 and the fourth cooling bed 52 are arranged on the other side of the first conveyor line 2 with respect to the first cooling bed 41 and the second cooling bed 42.

The fourth cooling bed 52 can further increase the air cooling efficiency of the second cooling bed mechanism 5, and has a better cooling effect. In addition, the conveying directions of the third cooling bed 51 and the fourth cooling bed 52 are reversely arranged, so that the plate can be conveyed in a roundabout way, the cooling distance of the cooling beds can be conveniently increased in a limited space, and the cooling effect is improved.

In the embodiment of the present utility model, a designer can adjust the specific configuration of the shearing mechanism according to the shearing requirement, and is not particularly limited herein. For example, the first shearing mechanism and the second shearing mechanism may each include a head shearing mechanism, a double-sided shearing mechanism, a fixed-length shearing mechanism, and the like, which are sequentially arranged in the conveying direction.

All articles and references, including patent applications and publications, disclosed herein are incorporated by reference for all purposes. The term "consisting essentially of …" describing a combination shall include the identified element, ingredient, component or step as well as other elements, ingredients, components or steps that do not substantially affect the essential novel features of the combination. The use of the terms "comprises" or "comprising" to describe combinations of elements, components, or steps herein also contemplates embodiments consisting essentially of such elements, components, or steps. By using the term "may" herein, it is intended that any attribute described as "may" be included is optional. Multiple elements, components, parts or steps can be provided by a single integrated element, component, part or step. Alternatively, a single integrated element, component, part or step may be divided into separate plural elements, components, parts or steps. The disclosure of "a" or "an" to describe an element, component, section or step is not intended to exclude other elements, components, sections or steps.

In this specification, each embodiment is described in a progressive manner, and each embodiment is mainly described by differences from other embodiments, and identical and similar parts between the embodiments are all enough to be referred to each other. The above embodiments are provided to illustrate the technical concept and features of the present utility model and are intended to enable those skilled in the art to understand the content of the present utility model and implement the same, and are not intended to limit the scope of the present utility model. All equivalent changes or modifications made in accordance with the spirit of the present utility model should be construed to be included in the scope of the present utility model.

Claims

1. A cooled panel production system, comprising:

2. The cooling type sheet material production system according to claim 1, wherein the second cooling mechanism includes a plurality of second cooling nozzles, and a second conveying line communicating with each of the second cooling nozzles, the plurality of second cooling nozzles being arranged at intervals on both upper and lower sides of the first conveying line, the second conveying line being capable of controllably inputting a cooling medium into each of the second cooling nozzles.

3. The cooling type sheet material production system according to claim 2, wherein the third cooling mechanism includes a plurality of third cooling nozzles, which are arranged at intervals on both upper and lower sides of the second conveying line, and a third conveying line communicating with each of the third cooling nozzles, which is capable of controllably inputting a cooling medium into each of the third cooling nozzles.

4. A cooled panel production system as claimed in claim 3 wherein the number of third cooling nozzles is less than the number of second cooling nozzles.

5. The chilled sheet production system of claim 1 wherein the rolling mechanism includes a roughing mill and a finishing mill disposed in sequence on the main mill line, the first cooling mechanism being disposed on the main mill line downstream of the finishing mill.

6. The cooled panel production system of claim 5 wherein the rolling mechanism further comprises a pre-straightener and a hot straightener disposed in sequence on the main line, the pre-straightener being disposed downstream of the finishing mill, the first cooling mechanism being disposed between the pre-straightener and the hot straightener.

7. The chilled sheet material production system of claim 1, wherein the first cooling mechanism includes a plurality of first cooling nozzles, and a first delivery line communicating with each of the first cooling nozzles, the plurality of first cooling nozzles being disposed in spaced apart relation on both upper and lower sides of the main mill train, the first delivery line being capable of controllably delivering a cooling medium into each of the first cooling nozzles.

8. The cooled panel production system of claim 1, wherein the first cooling bed mechanism comprises a first cooling bed, a second cooling bed, and a first cooling bed roller way, the first cooling bed and the second cooling bed are sequentially connected with the first conveyor line along the conveying direction of the first conveyor line, and the first cooling bed and the second cooling bed are connected through the first cooling bed roller way.

9. The cooled panel production system of claim 8 wherein the second cooling bed mechanism includes a third cooling bed that connects the first conveyor line and the second conveyor line.

10. The cooled panel production system of claim 9 wherein the second cooling bed mechanism further comprises a fourth cooling bed and a second cooling bed roller, the fourth cooling bed being connected to the outlet of the third cooling bed by the second cooling bed roller, the outlet of the fourth cooling bed being connected to the second conveyor line.