CN220790074U - Warehouse - Google Patents

Abstract

The application provides a warehouse, which comprises a floor and a warehouse body, wherein the warehouse body comprises a fixed gable, a movable bin and a driving component, the fixed gable is fixed on the floor, and the fixed gable is provided with a bin door capable of being opened and closed; one side of the movable bin is provided with an opening, the driving assembly is arranged on the movable bin, the movable bin is arranged on the floor, and the driving assembly drives the movable bin to move towards or away from the fixed gable on the floor so as to seal the opening or enable an operation opening for placing equipment to be formed between the movable bin and the fixed gable. The warehouse provided by the application has the effect of being convenient for placing large-scale electromechanical materials.

Description

Warehouse

Technical Field

The application relates to the technical field of storage equipment, in particular to a warehouse.

Background

In the construction process of hydraulic engineering, a plurality of large-scale electromechanical devices are usually used, and after the corresponding devices are transported to a construction site, the electromechanical devices are required to be stored in corresponding material warehouses so as to achieve the effects of moisture resistance, rain resistance, sun resistance, wind resistance and the like.

The mechanical and electrical material storage in the water conservancy construction process mainly has two forms: the outdoor storage is realized by adopting a mode of laying a lower cushion and a upper cover, wherein tarpaulin and square timber are laid at the bottom of the electromechanical equipment, and the tarpaulin is covered at the top, so that the mode is easy to produce missing moisture-proof, rain-proof and wind-proof effects, is unfavorable for the preservation of the electromechanical equipment, and is also insufficient in safety; another way is to store in a fixed warehouse, build a fixed warehouse at the construction site, and then place the supplies such as the electromechanical equipment into the fixed warehouse.

When the fixed warehouse is used for storing large overweight electromechanical equipment, the equipment is often placed in the warehouse by using machines such as a crane, a forklift and the like, and the warehouse on the construction site is small in construction under the limitations of site and economy and is difficult to accommodate the entrance of hoisting machines, so that the equipment is not beneficial to the storage and placement of large-scale equipment.

Disclosure of utility model

The application provides a warehouse, which is used for solving the problem that large electromechanical equipment is difficult to place in the warehouse.

The application provides a warehouse, which comprises a floor and a warehouse body, wherein the warehouse body comprises a fixed gable, a movable bin and a driving component, the fixed gable is fixed on the floor, and the fixed gable is provided with a bin door capable of being opened and closed;

One side of the movable bin is provided with an opening, the driving assembly is arranged on the movable bin, the movable bin is arranged on the floor, and the driving assembly drives the movable bin to move towards or away from the fixed gable on the floor so as to seal the opening or enable an operation opening for placing equipment to be formed between the movable bin and the fixed gable.

Optionally, remove the storehouse and include two side wall bodies, back wall body and ceiling, back wall body connects two side wall bodies, and the ceiling covers the top at two side wall bodies, and one side that two side wall bodies deviate from back wall body forms the opening with the ceiling jointly.

Optionally, a canopy is provided on the ceiling, and when the fixed gable is closed to be open, the fixed gable is positioned below the canopy.

Optionally, the one side of moving the storehouse towards fixed gable is provided with at least one first connecting portion, and the one side of fixed gable towards moving the storehouse is provided with at least one second connecting portion, and when fixed gable seals the opening, first connecting portion and second connecting portion connect.

Optionally, the driving assembly comprises at least one driving piece and a plurality of rollers, the rollers are respectively connected to the bottoms of the two side walls in a rotating mode, and the driving piece is used for driving the at least one roller to rotate.

Optionally, the floor comprises two rows of guide rail assemblies, the extending direction of the guide rail assemblies is consistent with the moving direction of the moving bin, the two rows of guide rail assemblies are respectively arranged on two sides of the floor, and the rollers are in contact with the guide rail assemblies and are in rolling connection with the guide rail assemblies.

Optionally, the guide rail assembly includes installation roof beam, I-beam and angle beam, and the installation roof beam is connected with the side on floor, and I-Liang Qian establishes in the installation roof beam, and the upper surface of I-beam flushes with the upper surface of installation roof beam, and the angle beam back-off is at the upper surface of I-beam, and gyro wheel roll connection is on the angle beam.

Optionally, the bottoms of two side wall bodies all are provided with the weather shield, and guide rail assembly is located between two weather shields, and the distance of the bottom of weather shield to the installation roof beam is less than the height of installation roof beam upper surface to the angle roof beam top.

Optionally, a plurality of claw ribs are arranged at the bottom of the I-beam, the claw ribs are embedded in the mounting beam, and the claw ribs and the I-beam are connected with the mounting beam through connecting pieces.

Optionally, both ends of guide rail assembly extending direction all are provided with the anticollision post, set up the locating part on the anticollision post, when moving storehouse and locating part contact, drive assembly orders about and moves the storehouse and stop moving.

According to the warehouse provided by the application, when large-scale electromechanical materials are required to be placed in the warehouse, the movable warehouse is driven to move towards one end far away from the fixed gable by the driving component, so that an operation port for placing the large-scale electromechanical materials is formed; then using crane and other machinery to directly hoist large electromechanical materials from the upper side of the operation port to the floor; and then moving back to the movable bin to be connected with the fixed gable, and closing the opening of the movable bin to form a complete warehouse, thereby realizing the storage and placement of large-scale electromechanical materials. The large electromechanical materials are placed in the warehouse in a mode of moving the movable warehouse, so that the large electromechanical materials are placed in the small warehouse, and meanwhile, the materials of the small pieces can be placed in the warehouse through the warehouse door, so that the normal use of the warehouse is not affected.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the application and together with the description, serve to explain the principles of the application.

Fig. 1 is a schematic structural diagram of a warehouse according to an embodiment of the present application;

Fig. 2 is a schematic structural view of another view of the warehouse according to the embodiment of the present application;

Fig. 3 is a schematic view of a partial structure of a fixed gable of a warehouse according to an embodiment of the present application;

fig. 4 is an enlarged schematic structural view of a rail assembly of a warehouse according to an embodiment of the present application.

Reference numerals illustrate:

100-floor;

200-warehouse body;

210-fixing gable walls;

211-a second connection;

212-bin gate;

220-moving the bin;

221-side wall;

222-rear wall;

223-ceiling;

224-canopy;

225-a first connection;

230-a drive assembly;

231-a driver;

232-a roller;

233-bearing;

234-supporting beams;

235-rain shield;

240-open;

250-operation port;

300-a rail assembly;

310-mounting a beam;

320-i-beams;

330-angle beam;

340-claw ribs;

350-anti-collision column;

360-limit piece.

Specific embodiments of the present application have been shown by way of the above drawings and will be described in more detail below. The drawings and the written description are not intended to limit the scope of the inventive concepts in any way, but rather to illustrate the inventive concepts to those skilled in the art by reference to the specific embodiments.

Detailed Description

Reference will now be made in detail to exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, the same numbers in different drawings refer to the same or similar elements, unless otherwise indicated. The implementations described in the following exemplary examples do not represent all implementations consistent with the application. Rather, they are merely examples of apparatus and methods consistent with aspects of the application as detailed in the accompanying claims.

The hydraulic engineering is a construction engineering which adopts scientific methods and technical measures and aims at water conservancy and water damage removal, and is also a basic element of social and economic basic facilities. But the water conservancy construction has the characteristics of large engineering scale and complex construction organization, and relates to the installation, debugging and construction of a large number of electromechanical devices. Because the electromechanical materials are high in cost and need to be stored in dry, dampproof and sun-proof environments, contact with rainwater is avoided, and most of water conservancy construction sites are open-air operation, so that the electromechanical materials cannot be effectively stored, and a simple warehouse is needed to be built for the electromechanical equipment. So as to achieve the conditions of dampproofing, rain proofing, sun protection, wind proofing and the like.

The mechanical and electrical material storage in the water conservancy construction process mainly has two forms: the outdoor storage is realized by adopting a mode of laying a lower cushion and a upper cover, wherein the bottom of the electromechanical equipment is provided with tarpaulin in a cushioning manner, and the top of the electromechanical equipment is covered with the tarpaulin, but the mode is easy to miss, has poor dampproof, rainproof and windproof effects, is unfavorable for the preservation of the electromechanical equipment, and has insufficient safety; another way is to store in a fixed warehouse, build a fixed warehouse at the construction site, and then place the supplies such as the electromechanical equipment into the fixed warehouse.

When a fixed warehouse is used for storing large and overweight electromechanical equipment, mechanical transportation such as a crane, a forklift and the like is often needed to place the equipment into the warehouse, but the warehouse on the construction site is small in construction under the limitation of site and economy, so that large electromechanical materials are difficult to place into the warehouse by using a machine.

In order to solve the problems, the application provides a warehouse, when large electromechanical materials are required to be placed in the warehouse, a driving component drives a movable warehouse to move towards one end far away from a fixed gable, so that an operation port for placing the large electromechanical materials is formed; then using crane and other machinery to directly hoist large electromechanical materials from the upper side of the operation port to the floor; and then moving back to the movable bin to be connected with the fixed gable, and closing the opening of the movable bin to form a complete warehouse, thereby realizing the storage and placement of large-scale electromechanical materials. The large electromechanical materials are placed in the warehouse in a mode of moving the movable warehouse, so that the large electromechanical materials are placed in the small warehouse, and meanwhile, the materials of the small pieces can be placed in the warehouse through the warehouse door, so that the normal use of the warehouse is not affected.

The following describes the technical scheme of the present application and how the technical scheme of the present application solves the above technical problems in detail with specific embodiments. The following embodiments may be combined with each other, and the same or similar concepts or processes may not be described in detail in some embodiments. Embodiments of the present application will be described below with reference to the accompanying drawings.

Fig. 1 is a schematic structural diagram of a warehouse according to an embodiment of the present application; fig. 2 is a schematic structural view of another view of the warehouse according to the embodiment of the present application; fig. 3 is a schematic view of a partial structure of a fixed gable of a warehouse according to an embodiment of the present application; fig. 4 is an enlarged schematic structural view of a rail assembly of a warehouse according to an embodiment of the present application.

As shown in fig. 1 and 2, the present application provides a warehouse, comprising a floor 100 and a warehouse body 200, wherein the warehouse body 200 comprises a fixed gable 210, a movable bin 220 and a driving assembly 230, the fixed gable 210 is fixed on the floor 100, and the fixed gable 210 is provided with a bin gate 212 which can be opened and closed;

One side of the moving bin 220 has an opening 240, the driving assembly 230 is disposed on the moving bin 220, the moving bin 220 is disposed on the floor 100, and the driving assembly 230 drives the moving bin 220 to move toward or away from the fixed gable 210 on the floor 100 to close the opening 240 or form an operation opening 250 for placing equipment between the moving bin 220 and the fixed gable 210.

When large electromechanical materials are required to be placed in the warehouse, the driving component 230 drives the movable bin 220 to move towards one end far away from the fixed gable 210, so that an operation port 250 for placing the electromechanical materials is formed; then using crane and other machinery to directly hoist large electromechanical materials from the upper side of the operation port 250 to the floor 100; and then the movable bin 220 is moved back to be connected with the fixed gable 210, and the opening 240 of the movable bin 220 is closed to form a complete warehouse, so that the large-scale electromechanical materials can be accessed and placed. The large electromechanical materials are placed into the warehouse by removing the moving magazine 220 to facilitate placement of the large electromechanical materials in the small warehouse.

In an alternative embodiment, as shown in fig. 2, the floor 100 is formed by concrete casting. The high-topography empty land is selected as the land of the warehouse, the floor 100 is cast on the ground, and the thickness of the cast floor 100 is 8 cm-12 cm, so that the moisture-proof effect of the bottom is improved. In other embodiments, the floor 100 may be formed by laying wood or steel, and the thickness of the floor 100 may be changed according to actual needs.

The fixed gable 210 is formed by welding a steel frame structure and a movable wallboard, namely, a movable wallboard forming mode is adopted, the construction is simple, convenient and quick, and the construction cost is reduced. The bottom of the fixing gable 210 is fixed to the upper surface of the end of the floor panel 100 using anchor bolts. The moving direction of the moving compartment 220 is the length direction of the floor panel 100. The length of the floor 100 is greater than or equal to twice the length of the moving bin 220 in the direction of movement. The length of the floor 100 is twice the length of the movable cabin 220, so that the operation opening 250 between the fixed gable 210 and the movable cabin 220 can be opened sufficiently, and large electromechanical materials can be placed at any position of the warehouse, so that more electromechanical materials can be placed conveniently, and meanwhile, the large electromechanical materials at any position of the warehouse can be taken out conveniently.

As shown in fig. 2, a door 212 is installed on the fixed gable 210 to be opened and closed. When placing small-size article, open door 212 can place small-size article in the warehouse, need not to remove the operation that removes storehouse 220 and opens and close operation mouth 250, and is more convenient, therefore in the storage of being convenient for to large-scale electromechanical material, compromise the placing of small-size article, great improvement the convenience of warehouse use.

As shown in fig. 1 and 2, optionally, the movable cabin 220 includes two side wall bodies 221, a rear wall body 222 and a ceiling 223, the rear wall body 222 is fixedly connected with the two side wall bodies 221 respectively, the length directions of the two side wall bodies 221 are parallel to the length direction of the floor 100, the ceiling 223 covers the tops of the two side wall bodies 221 and extends out of the side wall bodies 221, and one sides of the two side wall bodies 221 away from the rear wall body 222 and the ceiling 223 form an opening 240 together. After the movable bin 220 is separated from the fixed gable 210, the large-sized electromechanical materials can be suspended on the floor 100, so that the large-sized electromechanical materials can be placed.

As shown in fig. 1 and 2, in an alternative embodiment, the side wall bodies 221, the rear wall body 222 and the ceiling 223 are formed by splicing steel frame structures and wallboards, the ceiling 223 is a herringbone roof, two sides of the ceiling 223 are inclined, and two inclined ends of the ceiling 223 are fixedly overlapped on the two side wall bodies 221 and extend out of the side wall bodies 221 so as to guide rainwater out of a warehouse.

As shown in fig. 1, a canopy 224 is fixedly connected to the ceiling 223, and when the fixed gable 210 closes the opening 240, the fixed gable 210 is located below the canopy 224. The rain fly 224 shields the fixed gable 210 from rainwater flowing into the warehouse from the gap between the moving bin 220 and the fixed gable 210. When the fixed gable 210 closes the opening 240, two ends of the fixed gable 210 respectively abut against the inner walls of the two side wall bodies 221, which are close to each other.

The rain shed 224 may be integrally formed with the ceiling 223, or may be welded to an end of the ceiling 223 near the fixed gable 210, and the rain shed 224 is herringbone with the ceiling 223. The top of the corresponding fixed gable 210 is provided in a herringbone shape so that the weather shed 224 moves over the fixed gable 210 and extends to the outside of the fixed gable 210, thereby realizing shielding of the fixed gable 210.

As shown in fig. 1 and 3, optionally, a side of the movable compartment 220 facing the fixed gable 210 is provided with at least one first connection part 225, a side of the fixed gable 210 facing the movable compartment 220 is provided with at least one second connection part 211, and when the fixed gable 210 closes the opening 240, the first connection part 225 and the second connection part 211 are connected.

In the embodiment of the present application, two second connection portions 211 are disposed on the fixed gable 210, and one first connection portion 225 is disposed on each of the two side wall bodies 221 and corresponds to the two second connection portions 211 one by one.

The first connecting portion 225 is a first keyhole, the second connecting portion 211 is a second keyhole, the distance from the first keyhole to the upper surface of the floor 100 is equal to the distance from the second keyhole to the upper surface of the floor 100, and when the gable 210 is fixed to close the opening 240, the first keyhole is communicated with the second keyhole. At this time, the moving compartment 220 is fixed with the fixed gable 210 through the first and second buttonholes using the fixed lock. The safety of the warehouse is improved.

In other embodiments, when the fixed gable 210 closes the opening 240, a surface of the fixed gable 210 close to the moving bin 220 abuts against ends of the two side wall bodies 221; the first connection portion 225 may be a first locking ring fixed to the outer sidewall of the side wall 221, and the second connection portion 211 is a second locking ring fixed to the fixed gable 210, and when the fixed gable 210 closes the opening 240, the fixation between the movable bin 220 and the fixed gable 210 may be achieved by passing the first locking ring and the second locking ring through a chain and fixing the first locking ring and the second locking ring together.

Optionally, the driving assembly 230 includes at least one driving member 231 and a plurality of rollers 232, the plurality of rollers 232 are rotatably connected to bottoms of the two side wall bodies 221, respectively, and the driving member 231 is used for driving the at least one roller 232 to rotate.

As shown in fig. 4, the bottoms of the two side walls 221 are welded and fixed with supporting beams 234, and the length of the supporting beams 234 is the same as the length of the side walls 221. The roller 232 is connected with a bearing 233, and a frame of the bearing 233 is welded to the bottom of the supporting beam 234, thereby facilitating the movement of the moving bin 220. The rollers 232 on the supporting beam 234 are uniformly distributed, and the distance between two adjacent rollers 232 is greater than or equal to 2m and less than or equal to 3m. In the present application, the supporting beam 234 is made of square steel, and the supporting beam 234 is made of square steel, so that the supporting capability of the opposite side wall 221 is improved, and simultaneously, two opposite planes of the square steel are beneficial to the installation of the bearing 233 frame. The frame of the bearing 233 is welded to the bottom of the square steel, and the roller 232 is connected to the bearing 233.

In an alternative embodiment, the drive 231 is a motor gear mechanism. In the motor gear mechanism, a motor is arranged on a side wall 221, a gear is fixed on a roller 232, and the gear connected with the output end of the motor is meshed with the gear on the roller 232 to realize the transmission of the roller 232. In other embodiments, the driving member 231 may be a motor belt mechanism or a motor gear chain mechanism, etc. to drive the roller 232.

As shown in fig. 2, the movable cabin further comprises two rows of guide rail assemblies 300, wherein the extending direction of the guide rail assemblies 300 is consistent with the moving direction of the movable cabin 220, the two rows of guide rail assemblies 300 are respectively fixed on two sides of the floor 100, and the two rows of guide rail assemblies 300 are respectively positioned at the bottoms of the two side wall bodies 221. The roller 232 is in contact with the rail assembly 300 and is in rolling connection with the rail assembly 300.

As shown in fig. 4, the rail assembly 300 includes a mounting beam 310, an i-beam 320, and an angle beam 330, wherein the mounting beam 310 is connected to a side of the floor 100, the i-beam 320 is embedded in the mounting beam 310 to enhance a supporting capability, an upper surface of the i-beam 320 is flush with an upper surface of the mounting beam 310, the angle beam 330 is inverted on an upper surface of the i-beam 320, a cross section formed by the inverted angle beam 330 is a flat equilateral triangle, thereby forming a track, the roller 232 is rollably connected to a top of the angle beam 330, and a shape of the roller 232 is adapted to the cross section of the angle beam 330.

In an alternative embodiment, the mounting beams 310 are formed by casting reinforced concrete, the mounting beams 310 are cast together with the floor 100 while the casting is performed, and the upper surface of the mounting beams 310 is flush with the upper surface of the floor 100. The i-beam 320 is an i-beam, which is embedded in the mounting beam 310, and the upper surface of the i-beam is flush with the upper surface of the mounting beam 310. The angle beam 330 is angle steel, the angle steel is reversely buckled on the upper surface of the I-shaped steel and is welded and fixed, and the length of the bevel edge of the cross section of the angle steel is smaller than or equal to the length of the upper surface of the cross section of the I-shaped steel, so that the angle steel can be welded conveniently.

Optionally, the bottoms of the two side wall bodies 221 are provided with a rain shielding plate 235, the guide rail assembly 300 is located between the two rain shielding plates 235, and the distance from the bottom of the rain shielding plate 235 to the mounting beam 310 is smaller than the height from the upper surface of the mounting beam 310 to the top of the angle beam 330.

In the present application, the rain shield 235 is a steel plate, and the rain shield 235 is welded to a side of the square steel, which is far from the middle of the warehouse, or to a side of the sidewall body 221, which is far from the middle of the warehouse. In other embodiments, the weather barrier 235 may be a plastic and wood panel that is more lightweight to reduce the weight of the mobile bin 220. At this time, the weather shield 235 is fixed to the square steel or the side wall 221 by means of bonding or bolting. The distance from the bottom of the weather shield 235 to the mounting beam 310 is smaller than the height from the upper surface of the mounting beam 310 to the top of the corner beam 330, and the corner beam 330 protrudes to the upper surface of the mounting beam 310 so that the corner beam 330 and the weather shield 235 have partial overlap in the vertical direction, and thus, the rainwater splashed at the gap between the weather shield 235 and the mounting beam 310 is blocked by the protruding corner steel, thereby preventing the rainwater from entering the warehouse. Meanwhile, the wind power blown into the warehouse from the outside is weakened. On the premise of not influencing movement, the rainproof effect is realized.

As shown in fig. 4, optionally, a plurality of claw ribs 340 are provided at the bottom of the i-beam 320, the claw ribs 340 are embedded in the mounting beam 310, and the claw ribs 340 and the i-beam 320 are connected with the mounting beam 310 through connectors. The claw bar 340 is welded to the bottom surface of the i-beam 320. The connecting member is concrete, and when the mounting beam 310 is formed by pouring, the I-beam 320 welded with the claw ribs 340 is placed in the mounting beam 310, and then the mounting beam 310 is formed by pouring concrete, and meanwhile, the connection between the mounting beam 310 and the I-beam 320 is realized. The added I-beam 320 and the claw ribs 340 both strengthen the support strength of the diagonal beam 330 to facilitate the support of the moving bin 220 on the diagonal beam 330.

In an alternative embodiment, the plurality of claw ribs 340 are uniformly welded to the i-beam 320, and a distance between two adjacent claw ribs 340 is greater than or equal to 2m and less than or equal to 3m. The claw bar 340 includes a welding portion, two extending portions and two arc portions, the two extending portions are connected at two ends of the welding portion, and the two arc portions are separately connected at one ends of the two extending portions far away from the welding portion. The welding part, the extension part and the arc part are formed by bending the same steel bar. So that the supporting ability of the i-beam 320 is improved when the claw beam 340 is poured into the installation beam 310.

As shown in fig. 1, optionally, the two ends of the extending direction of the guide rail assembly 300 are provided with anti-collision columns 350, and the anti-collision columns 350 are provided with limiting members 360, and the limiting members 360 are configured such that, when the moving cabin 220 contacts with the limiting members 360, the driving assembly 230 drives the moving cabin 220 to stop moving.

In an alternative embodiment, the impact post 350 is formed by casting reinforced concrete, and the impact post 350 is fixedly attached to the mounting beam 310 and integrally cast with the mounting beam 310. The anti-collision post 350 near the fixed gable 210 is located at an end of the fixed gable 210 far from the movable bin 220, and a surface of the anti-collision post 350 near the movable bin 220 is flush with a surface of the fixed gable 210 far from the movable bin 220.

The anti-collision column 350 limits the displacement range of the movable cabin 220, avoids the possibility that the movable cabin 220 moves out of the floor 100, and meanwhile, the anti-collision column 350 on one side of the fixed gable 210 avoids the condition that the movable cabin 220 collides with the fixed gable 210, thereby avoiding the possibility that the movable cabin 220 collides with the fixed gable 210 in the moving process, and improving the safety.

The limiting member 360 includes a limiter and a controller, and the limiter is installed on one surface of the anti-collision post 350, which is close to the moving cabin 220. The limiter is a limit device such as a proximity switch or a travel limiter. The limiter is electrically connected to the controller, and the controller is electrically connected to the driving member 231. When the moving bin 220 contacts with the limiter, the limiter sends out a signal to the controller, and the controller sends out a corresponding indication signal to the driving piece 231, so that the driving piece 231 stops rotating the roller 232, and the moving bin 220 stops moving.

Through setting up of locating part 360, realized removing the effect that storehouse 220 stopped after storehouse 220 touched crashproof post 350 automatic control to make the operation simplify swiftly more, in order to make things convenient for operating personnel's daily use.

Other embodiments of the application will be apparent to those skilled in the art from consideration of the specification and practice of the application disclosed herein. This application is intended to cover any variations, uses, or adaptations of the application following, in general, the principles of the application and including such departures from the present disclosure as come within known or customary practice within the art to which the application pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the application being indicated by the following claims.

It is to be understood that the application is not limited to the precise arrangements and instrumentalities shown in the drawings, which have been described above, and that various modifications and changes may be effected without departing from the scope thereof. The scope of the application is limited only by the appended claims.

Claims (10)

1. The warehouse is characterized by comprising a floor and a warehouse body, wherein the warehouse body comprises a fixed gable, a movable bin and a driving assembly, the fixed gable is fixed on the floor, and the fixed gable is provided with a bin gate capable of being opened and closed;

One side of the movable bin is provided with an opening, the driving assembly is arranged on the movable bin, the movable bin is arranged on the floor, and the driving assembly drives the movable bin to move towards or away from the fixed gable on the floor so as to seal the opening or enable an operation opening for placing equipment to be formed between the movable bin and the fixed gable.

2. The warehouse as claimed in claim 1, wherein the movable compartment includes a rear wall, a ceiling and two side walls, the rear wall connects the two side walls, the ceiling covers the tops of the two side walls, and a side of the two side walls facing away from the rear wall and the ceiling form the opening together.

3. The warehouse as claimed in claim 2, wherein a canopy is provided over the ceiling, the fixed gable being positioned below the canopy when the fixed gable is closing the opening.

4. The warehouse according to claim 1, characterized in that the side of the moving bin facing the fixed gable is provided with at least one first connection part, the side of the fixed gable facing the moving bin is provided with at least one second connection part, and when the fixed gable closes the opening, the first connection part and the second connection part are connected.

5. A warehouse as claimed in claim 2, wherein the drive assembly includes at least one drive member and a plurality of rollers rotatably coupled to the bottoms of the two side walls, respectively, the drive member being configured to drive rotation of the at least one roller.

6. The warehouse as claimed in claim 5, further comprising two rows of rail assemblies, the extending direction of the rail assemblies is consistent with the moving direction of the moving bin, the two rail assemblies are disposed on both sides of the floor, and the rollers are in contact with the rail assemblies and are in rolling connection with the rail assemblies.

7. The warehouse as claimed in claim 6, wherein the rail assembly includes a mounting beam connected to a side of the floor, an i-beam Liang Qian provided in the mounting beam, an upper surface of the i-beam being flush with an upper surface of the mounting beam, and an angle beam inverted on an upper surface of the i-beam, the roller being rollably connected to the angle beam.

8. The warehouse as claimed in claim 7, wherein the bottom of both of the side walls are provided with a weather shield, the rail assembly is located between the two weather shields, and a distance from the bottom of the weather shield to the mounting beam is less than a height from the upper surface of the mounting beam to the top of the corner beam.

9. The warehouse as claimed in claim 7, wherein the bottom of the i-beam is provided with a plurality of claw ribs embedded in the mounting beam, and both the claw ribs and the i-beam are connected to the mounting beam by connectors.

10. The warehouse as claimed in claim 6, wherein the rail assembly has anti-collision posts at both ends in the extending direction, and the anti-collision posts have a stopper, and the driving assembly drives the moving bin to stop moving when the moving bin contacts with the stopper.