CN111300628A

CN111300628A - Autoclaved aerated concrete production line

Info

Publication number: CN111300628A
Application number: CN202010395823.4A
Authority: CN
Inventors: 付智红; 黄勃
Original assignee: Hunan Sany Kuaierju Housing Industry Co Ltd
Current assignee: Hunan Sany Kuaierju Housing Industry Co Ltd
Priority date: 2020-05-12
Filing date: 2020-05-12
Publication date: 2020-06-19
Anticipated expiration: 2040-05-12
Also published as: CN111300628B

Abstract

The embodiment of the invention provides an autoclaved aerated concrete production line, and relates to the technical field of component production lines. The autoclaved aerated concrete production line provided by the embodiment of the invention comprises a ferry vehicle, a conveying track and a plurality of autoclaves. The plurality of still kettles are arranged side by side along the first preset direction, the still kettles are provided with ferry areas along one side of the second preset direction, and the plurality of still kettles correspond to the ferry areas. The conveying track includes into cauldron track and line track down, advance cauldron track and line track down and correspond with ferry-boat region simultaneously, the ferry-boat setting is in ferry-boat region, thereby can realize advancing cauldron track and line track down and a plurality of ferry-boat demands of still pressing between the cauldron through evaporating the car of maintaining, consequently only set up one and advance cauldron track and line track down and also can satisfy a plurality of transport demands of evaporating the cauldron, thereby practiced thrift the space that sets up conveying track, practiced thrift the cost that sets up many conveying track, help reduce cost, and be favorable to evaporating the overall arrangement of pressing aerated concrete production line.

Description

Autoclaved aerated concrete production line

Technical Field

The invention relates to the technical field of component production lines, in particular to an autoclaved aerated concrete production line.

Background

Autoclaved aerated concrete (ALC) is a novel building material produced by taking sand, cement, lime, gypsum, aluminum powder and the like as materials, and the product of the ALC mainly comprises building blocks and plates, the production process of the building blocks and the plates is the same, the main production equipment is also the same, and the ALC mainly has the difference that the building blocks are made of pure autoclaved aerated concrete, and the plates are also provided with meshes besides the autoclaved aerated concrete.

At present, in the production process of autoclaved aerated concrete, a blank is placed into an autoclave for autoclave curing in saturated steam at 180-190 ℃ after being formed into a building block or a plate, so that a unique crystal structure is formed in the blank, and the product is endowed with higher strength and dimensional stability. The existing autoclaved aerated concrete production line occupies a large space, and further causes the problem of high production cost.

Disclosure of Invention

The invention aims to provide an autoclaved aerated concrete production line, which can reduce the occupied space area of the autoclaved aerated concrete production line and further help to reduce the production cost of autoclaved aerated concrete.

Embodiments of the invention may be implemented as follows:

the embodiment of the invention provides an autoclaved aerated concrete production line which comprises a ferry vehicle, a conveying rail and a plurality of autoclaves, wherein the autoclaves are arranged side by side along a first preset direction, one side of each autoclave along a second preset direction is provided with a ferry area, the autoclaves correspond to the ferry areas, and the ferry areas correspond to the conveying rail;

the conveying rail comprises a kettle feeding rail, the kettle feeding rail corresponds to the ferrying area, and the ferrying vehicle in the ferrying area is used for ferrying the steam-curing vehicle on the kettle feeding rail to the still kettle;

the conveying track further comprises an off-line track, the off-line track corresponds to the ferrying area, and the ferrying vehicle in the ferrying area is used for ferrying the steam maintenance vehicle in the still kettle to the off-line track.

Optionally, the kettle feeding track is provided with a plurality of caching stations, and the caching stations are used for caching a plurality of steaming cars simultaneously.

Optionally, the autoclaved aerated concrete production line further comprises a heat preservation device arranged at the position of the kettle inlet rail, and the heat preservation device is used for preserving heat of the semi-finished autoclaved aerated concrete on the cache station.

Optionally, one side of the kettle entering rail along the first preset direction is provided with a first processing area, and the first processing area is used for placing a production system for producing semi-finished autoclaved aerated concrete.

Optionally, the production system includes a cutting device and a semi-finished product crane, the cutting device and the kettle feeding rail are arranged side by side, and the semi-finished product crane corresponds to the cutting device and the kettle feeding rail respectively, so as to hoist the semi-finished product autoclaved aerated concrete formed by cutting by the cutting device to the kettle feeding rail.

Optionally, a second processing area is arranged on one side of the kettle entering rail, which is far away from the first processing area, and the second processing area is used for placing a mesh processing system.

Optionally, the kettle feeding track is located on one side of the ferrying area, which is far away from the still kettle, and the kettle feeding track and the ferrying area enclose the first processing area.

Optionally, the kettle feeding track and the offline track are respectively located on two sides of the ferry area along the second preset direction.

Optionally, the offline track is located on one side of the ferry area close to the still kettle.

Optionally, the autoclaved aerated concrete production line further comprises a lower line conveying line, wherein the lower line conveying line corresponds to the lower line track, so that the steam-curing car on the lower line track can be transferred to the lower line conveying line.

The autoclaved aerated concrete production line provided by the embodiment of the invention has the beneficial effects of:

the embodiment of the invention provides an autoclaved aerated concrete production line which comprises a ferry vehicle, a conveying track and a plurality of autoclaves. The plurality of still kettles are arranged side by side along the first preset direction, the still kettles are provided with ferry areas along one side of the second preset direction, and the plurality of still kettles correspond to the ferry areas. The conveying track includes into cauldron track and line track down, advance cauldron track and line track down and correspond with ferry-boat region simultaneously, ferry-boat car sets up in ferry-boat region, thereby can realize advancing cauldron track and line track down and a plurality of ferry-boat demands of evaporating still cauldron through evaporating the foster car, consequently even only set up one and advance cauldron track and line track down and also can satisfy a plurality of transport demands of evaporating still cauldron, thereby practiced thrift the space that sets up conveying track, practiced thrift the cost that sets up many conveying track, help reduce cost, and can create the advantage for the overall arrangement of follow-up other equipment that evaporate and press the aerated concrete production line, be favorable to evaporating the overall arrangement of evaporating aerated concrete production line promptly.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

Fig. 1 is a schematic view of the overall structure of an autoclaved aerated concrete production line provided by an embodiment of the present invention;

FIG. 2 is a schematic view of a partial structure of an autoclaved aerated concrete production line provided by an embodiment of the present invention;

fig. 3 is a schematic structural diagram of an offline conveying area of an autoclaved aerated concrete production line according to an embodiment of the present invention.

Icon: 100-autoclaved aerated concrete production line; 110-an autoclaved area; 111-still kettle; 112-steam curing vehicle; 120-ferry area; 121-ferry vehicle; 130-a conveying track; 131-a kettle entering track; 132-down line track; 140-a first processing zone; 141-a production system; 142-a cutting device; 143-semi-finished product crane; 144-feedstock processing equipment; 145-a forming device; 150-a second processing zone; 151-mesh processing system; 160-off-line delivery area; 161-offline conveying line; 162-finished product crane; 163-finished product upender; 164-breaking-off machine; 165-a pinch roll machine; 166-block conveyor line; 167-plate conveying line; 170-air steam curing bottom plate circulation conveying line.

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 present invention, it should be noted that if the terms "upper", "lower", "inside", "outside", etc. indicate an orientation or a positional relationship based on that shown in the drawings or that the product of the present invention is used as it is, this is only for convenience of description and simplification of the description, and it does not indicate or imply that the device or the element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention.

Furthermore, the appearances of the terms "first," "second," and the like, if any, are used solely to distinguish one from another and are not to be construed as indicating or implying relative importance.

It should be noted that the features of the embodiments of the present invention may be combined with each other without conflict.

6 steam-curing cars can be parked in the still kettle, a track is arranged in front of the still kettle in the existing steam-curing aerated concrete production line, the steam-curing cars are ferred to the track by the ferry car, and after the 6 steam-curing cars are integrally woven, the 6 steam-curing cars are sent into the still kettle together by a tractor for steam-curing. The inventor finds that a plurality of steam-curing kettles are often arranged in an autoclaved aerated concrete production line, so that a plurality of tracks which correspond to the steam-curing kettles one by one need to be arranged, the occupied area of the plurality of tracks is large, each track works for less than 3 hours every day, and space and cost are greatly wasted.

Fig. 1 is a schematic view of an overall structure of an autoclaved aerated concrete production line 100 provided in this embodiment, and fig. 2 is a schematic view of a partial structure of the autoclaved aerated concrete production line 100 provided in this embodiment. Referring to fig. 1 and fig. 2, this embodiment provides an autoclaved aerated concrete production line 100. The autoclaved aerated concrete production line 100 comprises a ferry vehicle 121, a conveying track 130 and a plurality of autoclaves 111. The multiple still kettles 111 are arranged side by side along the first preset direction, a ferry area 120 is arranged on one side of the still kettles 111 along the second preset direction, and the multiple still kettles 111 correspond to the ferry area 120. The conveying rails 130 comprise a kettle inlet rail 131 and a lower line rail 132, the kettle inlet rail 131 and the lower line rail 132 correspond to the ferry area 120 at the same time, and the ferry vehicle 121 is arranged in the ferry area 120, so that the ferry vehicle 121 can be switched between the still kettles 111 and the conveying rails 130 through the movement of the ferry vehicle 121 in the ferry area 120, and the ferry requirements between the kettle inlet rail 131 and the lower line rail 132 and a plurality of still kettles 111 can be realized through the steam-curing vehicle 112, therefore, even if only one kettle inlet rail 131 and one lower line rail 132 are arranged, the conveying requirements of the plurality of still kettles 111 can be met, the space for arranging the conveying rails 130 is saved, the cost for arranging the plurality of conveying rails 130 is saved, and the cost is reduced.

The autoclaved aerated concrete production line 100 provided in this embodiment is further described below:

referring to fig. 1 and fig. 2, in the present embodiment, the first predetermined direction (a-b direction shown in fig. 1 and fig. 2) is perpendicular to the second predetermined direction (c-d direction shown in fig. 1 and fig. 2), specifically, the first predetermined direction is a width direction of the factory building, and the second predetermined direction is a length direction of the factory building.

One side of the still kettle 111 in the second preset direction is provided with a ferry area 120, and the ferry area 120 is a movement area of the ferry vehicle 121. It should be noted that, in the description of the present embodiment, "correspond" means that the autoclaved aerated concrete (not shown) can be transferred between the plurality of autoclaves 111 and the ferry area 120, that is, when the plurality of autoclaves 111 correspond to the ferry area 120, the autoclaved aerated concrete on the steam-curing vehicle 112 can be transferred between the autoclaves 111 and the ferry area 120, and when the conveying rail 130 corresponds to the ferry area 120, the autoclaved aerated concrete on the steam-curing vehicle 112 can be transferred between the conveying rail 130 and the ferry area 120. Therefore, the steam-curing cars 112 in each autoclave 111 can be transferred to the conveying rail 130 or the steam-curing cars 112 in the conveying rail 130 can be transferred to any autoclave 111 by the ferry motion of the ferry car 121 in the ferry area 120. In other words, only one conveying track 130 is needed to meet the kettle entering or kettle exiting requirements of a plurality of still kettles 111, and the number and the occupied space area of the conveying tracks 130 are greatly reduced.

In this embodiment, the conveying track 130 includes a tank feeding track 131, and the autoclaved aerated concrete loaded in the steam-curing vehicle 112 on the tank feeding track 131 is a semi-finished autoclaved aerated concrete that has not undergone autoclave curing. Specifically, the tank inlet track 131 is provided with a plurality of buffer stations, and each buffer station can buffer one steam-curing vehicle 112, so that a plurality of steam-curing vehicles 112 can be buffered through the plurality of buffer stations, in other words, the tank inlet track 131 is long enough to meet the requirement of simultaneous buffer of a plurality of steam-curing vehicles 112. The kettle entering rail 131 corresponds to the ferry area 120, and the ferry vehicle 121 in the ferry area 120 is used for ferrying the steam-curing vehicle 112 entering the kettle rail 131 into the still kettle 111, so that the semi-finished product in the steam-curing vehicle 112 is steam-cured by the still kettle 111. Specifically, one end of the autoclave 111 in the second predetermined direction has an opening (not shown) that communicates the space in the autoclave 111 with the ferry area 120, so that the steam-curing cars 112 in the ferry area 120 can be fed into the autoclave 111 through the opening.

Because a plurality of steam-curing vehicles 112 can be placed in each autoclave 111 at the same time to perform steam-curing on the semi-finished product autoclaved aerated concrete in the plurality of steam-curing vehicles 112, and the ferry vehicle 121 can only ferry one steam-curing vehicle 112 to the autoclave 111 in sequence, a large amount of time is consumed for ferrying the plurality of steam-curing vehicles 112, so as to avoid heat loss of the semi-finished product autoclaved aerated concrete in the steam-curing vehicle 112 when the steam-curing vehicle 112 on the autoclave track 131 waits for ferry, further, the autoclaved aerated concrete production line 100 further comprises a heat preservation device (not shown) arranged at the autoclave track 131, wherein the heat preservation device can preserve heat of the semi-finished product autoclaved aerated concrete on the autoclave track 131, in other words, the heat preservation device is used for preserving heat of the semi-finished product autoclaved aerated concrete on the cache station, thereby ensuring that the inside and outside temperatures of the semi-finished product autoclaved aerated concrete are consistent. In this embodiment, 6 steam-curing cars 112 can be placed in each autoclave 111 at the same time.

With reference to fig. 1 and fig. 2, in the present embodiment, a first processing area 140 is disposed on one side of the tank entering track 131 along a first predetermined direction, and the first processing area 140 is used for placing a production system 141 for producing a semi-finished autoclaved aerated concrete. Further, the kettle feeding track 131 and the plurality of autoclaves 111 are respectively located at two sides of the ferry area 120, in other words, the kettle feeding track 131, the ferry area 120 and the plurality of autoclaves 111 are sequentially arranged along the second preset direction. The tank inlet rail 131 and the ferry area 120 enclose the first processing area 140. Optionally, the conveying direction of the kettle entering rail 131 extends along the second preset direction.

Further, the production system 141 comprises a cutting device 142 and a semi-finished product crane 143, the cutting device 142 is arranged side by side with the kettle entering rail 131, and the semi-finished product crane 143 corresponds to the cutting device 142 and the kettle entering rail 131 respectively, so that the semi-finished product autoclaved aerated concrete formed by cutting by the cutting device 142 is hoisted to the steam-curing vehicle 112 on the kettle entering rail 131 through the semi-finished product crane 143. Specifically, the semi-finished product crane 143 is disposed at an end of the kettle entering rail 131 away from the ferry area 120. Further, the production system 141 further includes a material processing device 144 and a forming device 145, and the material processing device 144 and the forming device 145 are both disposed on a side of the cutting device 142 away from the tank feeding rail 131.

Further, a second processing area 150 is disposed on a side of the kettle entering rail 131 far from the first processing area 140, that is, along the first predetermined direction, the first processing area 140, the kettle entering rail 131 and the second processing area 150 are sequentially disposed. The second processing area 150 is used for placing a mesh sheet processing system 151, and the mesh sheet processing system 151 is used for processing mesh sheets, so that the mesh sheets are added into the slurry of the autoclaved aerated concrete to form the plate. Because only one kettle entering track 131 is arranged, a large amount of space is saved, the mesh processing system 151 can be arranged in the saved space, the layout is more compact, all parts in the autoclaved aerated concrete production line 100 are arranged on the same side, and the processed mesh can be directly applied to plate production and is more convenient.

With reference to fig. 1 and fig. 2, in the present embodiment, the conveying track 130 further includes an offline track 132, and the autoclaved aerated concrete loaded in the steam-curing car 112 on the offline track 132 is the finished autoclaved aerated concrete after steam-curing. Specifically, the number of the off-line rails 132 is one or more, and the off-line rails 132 can simultaneously carry the steam-curing cars 112 in at least one steam-curing kettle.

The lower line rail 132 corresponds to the ferry area 120, and the ferry vehicles 121 in the ferry area 120 are used for ferrying the steam-curing vehicles 112 in the still kettles 111 into the lower line rail 132 and finally transferring through the lower line rail 132. Therefore, the autoclaved aerated concrete production line 100 only needs to arrange the ferry area 120 at one side of the still kettle 111, and the ferry vehicle 121 in the ferry area 120 drives the steam-curing vehicle 112 to enter and exit the still kettle through the opening of the still kettle 111, so that the space is further saved.

In this embodiment, the offline track 132 and the kettle entering track 131 are respectively located on two sides of the ferry area 120 along the second preset direction. Further, the offline track 132 is located at one side of the ferry area 120 close to the autoclaves 111, that is, along the first preset direction, the autoclaves 111 and the offline track 132 are sequentially arranged. Optionally, the lower line track 132 and the kettle entering track 131 are arranged at intervals along a second preset direction, and a space between the lower line track 132 and the kettle entering track 131 and extending to the autoclave 111 farthest from the lower line track 132 is the ferry area 120. The offline track 132 and the ferry area 120 enclose an autoclaved area 110, and a plurality of autoclaves 111 are all arranged in the autoclaved area 110.

Fig. 3 is a schematic structural view of the conveying area 160 of the autoclaved aerated concrete production line 100 according to this embodiment. Referring to fig. 1 and 3, a lower line conveying area 160 is further disposed on one side of the lower line track 132. The autoclaved aerated concrete production line 100 further comprises a lower line conveying line 161, and the lower line conveying line 161 is arranged in the lower line conveying area 160. And the lower line transfer line 161 corresponds to the lower line rail 132 so that the steaming cart 112 on the lower line rail 132 can be transferred to the lower line transfer line 161. Specifically, the unloading line 161 includes a finished product crane 162, a finished product turning machine 163, an severing machine 164, a blank holder 165, a block line 166, and a board line 167. The finished product crane 162 corresponds to the finished product turnover machine 163 and the lower track 132 at the same time, the finished product autoclaved aerated concrete on the lower track 132 is transferred to the finished product turnover machine 163 through the finished product crane 162, and then transferred to the blank clamping machine 165 after passing through the breaking-off machine 164, the finished product autoclaved aerated concrete is divided into building blocks and plates according to whether meshes exist in the finished product autoclaved aerated concrete, the building block conveying line 166 and the plate conveying line 167 correspond to the blank clamping machine 165, when the finished product autoclaved aerated concrete entering the blank clamping machine 165 is a building block, the finished product autoclaved aerated concrete is transferred to the building block conveying line 166 through the blank clamping machine 165, and when the finished product autoclaved aerated concrete entering the blank clamping machine 165 is a plate, the finished product autoclaved aerated concrete is transferred to the plate conveying line 167 through the blank clamping machine 165.

Further, the autoclaved aerated concrete production line 100 further comprises an empty steam curing bottom plate circulation conveying line 170, one end of the empty steam curing bottom plate circulation conveying line 170 is located between the lower line rail 132 and the finished product overturning machine 163, and the other end of the empty steam curing bottom plate circulation conveying line passes through the area between the kettle feeding rail 131 and the mesh sheet processing system 151 and extends to the semi-finished product crane 143. To transfer the steam-cured soleplate to the tank-entering rail 131 by the semi-finished product crane 143.

According to the autoclaved aerated concrete production line 100 provided by the embodiment, the working principle of the autoclaved aerated concrete production line 100 is as follows:

when the semi-finished product autoclaved aerated concrete is used, firstly, the semi-finished product autoclaved aerated concrete is produced through the production system 141, and is transferred to the kettle entering track 131 for caching, and heat preservation is carried out through the heat preservation device on the kettle entering track 131. The ferry vehicle 121 in the ferry area 120 ferries and transfers the steam-curing vehicle 112 carrying the semi-finished product autoclaved aerated concrete on the kettle track 131 to the steam-curing kettle, after the steam-curing kettle is filled with a group of steam-curing vehicles 112, the steam-curing kettle carries out steam-curing on the semi-finished product autoclaved aerated concrete in the steam-curing kettle, the semi-finished product autoclaved aerated concrete becomes the finished product autoclaved aerated concrete after the steam-curing, and the ferry vehicle 121 in the ferry area 120 ferry transfers the steam-curing vehicle 112 carrying the finished product autoclaved aerated concrete to the lower line track 132, and finally the finished product autoclaved aerated concrete is conveyed through the lower line conveying line 161.

The finished autoclaved aerated concrete provided by the embodiment at least has the following advantages:

according to the finished autoclaved aerated concrete provided by the embodiment of the invention, the ferry area 120 is arranged between the conveying track 130 and the autoclaves 111, so that the requirement of entering or exiting a plurality of autoclaves 111 can be met by only arranging one conveying track 130, the arrangement space is effectively saved, and compared with the traditional layout, equipment such as a tractor or a crane for entering or exiting the autoclaves is omitted, and the cost is reduced. Meanwhile, the conveying rail 130 comprises a kettle inlet rail 131 and a lower line rail 132 which are oppositely arranged, the kettle inlet rail 131 and the lower line rail 132 correspond to the same ferrying area 120, so that the space is further saved, compared with the traditional layout, the area of a factory building can be reduced by about 35%, the cost is reduced, and the enough space arrangement mesh processing system 151 is arranged in the factory building with only one layer. The number of the kettle entering rails 131 and the lower line rails 132 is greatly reduced, so that the cost for arranging the kettle entering rails 131 and the lower line rails 132 is also reduced.

The above description is only for the specific embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention are included in the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the appended claims.

Claims

1. The autoclaved aerated concrete production line is characterized by comprising a ferry vehicle (121), a conveying rail (130) and a plurality of autoclaves (111), wherein the autoclaves (111) are arranged side by side along a first preset direction, a ferry area (120) is arranged on one side of the autoclaves (111) along a second preset direction, the autoclaves (111) correspond to the ferry area (120), and the ferry area (120) corresponds to the conveying rail (130);

the conveying track (130) comprises a kettle entering track (131), the kettle entering track (131) corresponds to the ferrying area (120), and the ferrying vehicle (121) in the ferrying area (120) is used for ferrying the steam-curing vehicle (112) on the kettle entering track (131) to the still kettle (111);

the conveying track (130) further comprises a lower line track (132), the lower line track (132) corresponds to the ferrying area (120), and a ferry vehicle (121) in the ferrying area (120) is used for ferrying a steam-curing vehicle (112) in the still kettle (111) to the lower line track (132).

2. The autoclaved aerated concrete production line according to claim 1, characterized in that the still entering track (131) has a plurality of buffer stations for buffering a plurality of retort carts (112) simultaneously.

3. The autoclaved aerated concrete production line according to claim 2, wherein the autoclaved aerated concrete production line (100) further comprises a heat preservation device arranged at the position of the still inlet rail (131), and the heat preservation device is used for preserving heat of the semi-finished autoclaved aerated concrete on the caching station.

4. The autoclaved aerated concrete production line according to claim 1, wherein one side of the tank inlet rail (131) along the first preset direction is provided with a first processing area (140), and a production system (141) for producing semi-finished autoclaved aerated concrete is arranged in the first processing area (140).

5. The autoclaved aerated concrete production line according to claim 4, wherein the production system (141) comprises a cutting device (142) and a semi-finished product crane (143), the cutting device (142) is arranged side by side with the kettle entering rail (131), and the semi-finished product crane (143) corresponds to the cutting device (142) and the kettle entering rail (131) respectively, so as to crane the semi-finished product autoclaved aerated concrete formed by cutting by the cutting device (142) to the kettle entering rail (131).

6. The autoclaved aerated concrete production line according to claim 4, characterized in that the side of the tank inlet track (131) remote from the first processing area (140) has a second processing area (150), the second processing area (150) being used for placing a mesh processing system (151).

7. The autoclaved aerated concrete production line according to claim 4, wherein the tank inlet rail (131) is located on the side of the ferry area (120) away from the still tank (111), and the tank inlet rail (131) and the ferry area (120) enclose the first processing area (140).

8. The autoclaved aerated concrete production line according to claim 1, wherein the kettle entry track (131) and the lower line track (132) are respectively located on both sides of the ferry area (120) in the second preset direction.

9. The autoclaved aerated concrete production line according to claim 1, characterized in that the down-line track (132) is located on the side of the ferry area (120) close to the still kettle (111).

10. The autoclaved aerated concrete production line according to claim 1, characterized in that the autoclaved aerated concrete production line (100) further comprises a lower line conveying line (161), the lower line conveying line (161) corresponds to the lower line rail (132) so that the steam-curing cars (112) on the lower line rail (132) can be transferred to the lower line conveying line (161).