RU2033378C1 - System to prepare containers for unloading from vehicle - Google Patents

Abstract

FIELD: container unloading. SUBSTANCE: system has framework with load trolley which mounts container lifting, turning and deflecting mechanisms. Adjustable supports are mounted on ramp arranged along framework. Container deflecting mechanism is made in form of hinged parallelogram. EFFECT: enlarged operating capabilities. 3 cl, 9 dwg

Description

 The invention relates to the field of mechanization of loading and unloading operations, in particular to devices for preparing containers for performing the final operations of loading them with goods and unloading goods from them.

 One of the most advanced methods of transporting packaged goods is container in the framework of the transport and technological system using large-capacity containers of international standard. The containers are delivered to final destinations by rail on special platforms carrying 2-3 twenty-ton containers installed with doors inward, or by road on special semi-trailers with truck tractors carrying 1-2 twenty-ton containers. The final operations to unload goods from the container and load the goods into the container are preceded by a series of operations to prepare the container for unloading or loading of goods.

 Known devices and systems for preparing the container for the final operations of loading goods into the container and unloading them from the container, which include a number of technical means that perform intermediate operations necessary for their implementation. Such devices include, for example, conventional ramps with a bridge (Afanasyev L. L. Ostrovsky M. V. Zuckerberg S. M. Unified transport system and road transport. M. Transport, 1984, pp. 227-229). When using them, the container mounted on the vehicle is fed with a doorway close to the ramp. Unloading cargo from the container is carried out manually. For use of loaders, a bridge is installed between the ramp cover and the container floor.

 Usually, bridges of a special design are used, consisting of three elements: an entrance, a platform and an exit, having a fence, and installed in front of the container door. The width of these bridges is equal to the internal width of the container, the carrying capacity is at least 5 tons. In Canada and the USA, similar mobile type bridges are used (V. Osipova, Containerization in foreign countries. VINITI, USSR Academy of Sciences. M. Nauka, 1975, p. 114).

 These devices do not solve the problem of mechanized processing of containers arriving on railway platforms, and two containers on one semitrailer.

Known gantry cranes on the railway and air passage. Such, for example, is a gantry crane comprising a superstructure, a freight trolley with a swivel carriage and a support ring equipped with movement and rotation mechanisms. The lifting mechanism contains a winch and a vertical lifting column to which a spreader is attached (Container transport system / Ed. By A.T. Deribass. M. Transport, 1974, p. 197-198). Gantry crane provides lifting the container to the desired height, moving outside of the vehicle and lowering on Vnutriskladskaya vehicle or on the ground with, if necessary, turn to ^180.

The disadvantages of the known device are its low performance:
the need for an exchange fleet of containers or in a large investment of time for a vehicle to wait for a container to return at the end of the entire complex of operations for its processing,
the presence in the process chain for preparing the container for loading or unloading cargo from it several lifting machines: a gantry crane, a warehouse vehicle, a special loader, a bridge, a forklift;
significant energy and labor costs for lifting and moving the container;
the complexity and bulkiness of the device for lifting and moving the container.

 Closest to the technical nature of the present invention is a system for preparing containers for unloading from a vehicle. The system comprises a landing structure mounted on mobile supports with a cargo trolley moving along the span, carrying a lifting mechanism associated with the spreader, and a ramp located along the span. The system provides removal of the container from the vehicle (railway or automobile), its subsequent movement outside the vehicle and its installation on a ramp for on-site processing or for movement by an internal storage vehicle for storage.

 The disadvantages of the known system is low system performance; the inability to use special progressive devices, for example, air cushion transport devices, for unloading cargo from a container (loading cargo into a container); significant energy costs for lifting and moving the container; the need to move the container outside the vehicle; complexity and bulkiness of the system.

 The purpose of the invention is the elimination of these disadvantages, namely: reducing material and energy costs (resources) for the totality of operations for preparing the container for unloading and loading and simplifying the design of the system, i.e. expanding technological capabilities and increasing productivity. This allows you to reduce the resources spent on cargo operations.

 This goal is achieved in that the system for preparing containers for unloading from a vehicle, comprising a superstructure with a freight trolley, carrying a lifting mechanism associated with the spreader, and a ramp located along the superstructure, is equipped with a swivel mechanism fixed to the trolley on which the mechanism is mounted container deflection formed by an articulated parallelogram associated with the drive. On the hinged parallelogram, a lifting mechanism is fixed, made with the possibility of gripping and releasing the container mounted with an inclination. Height-adjustable supports for mounting the container are mounted on the ramp. The lifting mechanism is made in the form of four hydraulic cylinders, the body of which is fixed on the lower edge of the articulated parallelogram, and the rod is pivotally connected to the spreader. The drive of the deflection mechanism is made in the form of a hydraulic cylinder pivotally connected by a housing by means of an arm with a rotary mechanism, and a rod with a lower edge of the articulated parallelogram.

Known technical solutions have certain features similar to some of the distinguishing features of the claimed invention: span, cargo trolley, lifting mechanism, ramp, bearings, articulated joints, hydraulic cylinders. However, the proposed combination of features is unknown: the relative position of known parts and assemblies, their combination and connections, the form of connections that provide high processing efficiency of containers at the final points. The proposed system, the totality of its elements, predetermine such a feature of operations performed using this particular system that ensure the processing of the container without removing it outside the vehicle and thereby significantly reduce the resources spent on cargo operations. The presence of a lifting mechanism, for example, in the form of four hydraulic cylinders, the housing of which is fixed on the lower edge of the articulated parallelogram of the deflection mechanism (i.e., pairwise connected), in conjunction with the deflection mechanism, which is formed by the articulated parallelogram connected to the drive, and in conjunction with the fixed on the trolley with a rotary mechanism, the container is lifted above the vehicle with its subsequent deviation by movement (by means of the articulated parallelogram hydraulic cylinder) from the adjacent its possibility to rotate ^about 90, and for lowering the adjustable feet ramp inclined pairwise connected via hydraulic cylinders of the lifting mechanism. It eliminates the need to move the container outside the vehicle, lower it to the platform or to the inside storage vehicle (semitrailer, roll trailer), move it inside the storage vehicle (loader, tractor) to the ramp, and therefore, it becomes possible to handle the container almost in place (above the transport means and in this way to save material and energy costs).

 The presence of adjustable supports on the frame together allows you to open the container doors and subsequent docking with the ramp (by lowering one of the adjustable supports on the ramp until the container floor and ramp are aligned), eliminates the need for a bulky complex transition bridge between the container floor and the ramp, loader cover for its installation, and also allows you to use mechanization tools to handle the container, providing loading of the container with heavy packages (devices on the air cushion, mini-roll-railers, lever devices, etc.), which increases the intensity of processing the container at the end points.

 The supply of the system with a rotary mechanism ensures the combination of the container with the ramp without moving the container outside the vehicle, which also simplifies the mechanism for moving the cargo trolley.

The possibility (due to this combination) of insignificant lifting of the container and its rotation over the vehicle by 90 ^° allows ^us to sufficiently simplify the lifting and turning mechanisms and reduce energy costs for performing the corresponding operations. Providing the rotary mechanism with the mechanism of deflection of the container allows you to handle vehicles transporting two or three containers, installed close to each other with doors inward. It is not necessary to move the entire cargo trolley, it is enough just to turn the container to be handled from the adjacent container to a limited distance before turning. The installation of height-adjustable supports on the ramp together allows you to create the slope needed to open the container door, since the doors are below the level of the container floor, and also allows you to create a slope that facilitates loading or unloading the container, and thus reduces energy costs for performing these operations (especially when using air cushion devices). The implementation of the lifting mechanism in the form of four hydraulic cylinders allows in this combination to simplify the lifting mechanism itself and to ensure the capture and release of the container installed with one or another slope (by pairwise turning on the hydraulic cylinders), i.e. creates an additional beneficial effect.

 Implementation of the drive mechanism of the container deflection in the form of a hydraulic cylinder, fixed by the body through the bracket to the rotary mechanism, and the rod to the lower edge of the hinged parallelogram, provides its simplicity, small dimensions and high performance.

 Thus, the present invention has wider technical capabilities and higher productivity, ensuring the effective implementation of the final operations of container-packet transportation of goods using various means of mechanization of unloading and loading of containers and package sizes.

 In FIG. 1 shows a device inoperative, front view; in FIG. 2 same, top view; in FIG. 3 same side view; in FIG. 4 cargo trolley, side view; in FIG. 5 the same, top view; in FIG. 6 shows the moment of opening the doors of the container after its rotation and lowering to the supports, side view; in FIG. 7 shows the moment of docking the container with the ramp after opening the doors, side view; in FIG. 8 node I in FIG. 6; in FIG. 9 node II in FIG. 7.

 The system 1 comprises a span structure 2 located along the ramp 3 and height-adjustable supports 4 and 5 located on opposite sides of the vehicle 6. A rotary mechanism 8 with guides 9 made in the form of a support ring and with a support ring is placed on the cargo trolley 7 bearing 10 along the axis of the ring, mounted on the frame 11 of the cargo truck 7. The rotary mechanism 8 is equipped with a mechanism for deflecting the container 12, made in the form of a hinged parallelogram 13, the upper face of which is rigidly fixed to the rotary mechanism 8, and the lower one is pivotally connected to the rod 14 of the hydraulic cylinder, the housing 15 of which is connected to the rotary mechanism 8 via the bracket 16. The lifting mechanism is made in the form of four hydraulic cylinders, the housing 17 of which are pivotally mounted on the lower face 18 of the deflection mechanism 13, and the rods 19 are pivotally connected to the spreader 20. Supports 4 and 5 are mounted with the possibility of vertical movement by means of a hydraulic cylinder 21 with a rod 22. The support 5 is provided with guides 23 to facilitate the alignment of the container during its installation. On the ramp 3, a ledge 24 for placing the end face of the container 12 is made. The freight trolley 7 is equipped with wheels 25 mounted on guides 26 laid on the lower belt 27 of the span 2. The support 44 is equipped with a transition bridge 28 having a frame 29 that overlaps the gap between the cover 30 of the ramp 3 and floor 31 of container 12.

The system operates as follows. A vehicle 6 (for example, a platform) with two 20-ton containers is fed to the ramp 3 and installed under the span 2. The cargo trolley 7 is moved along the span 2 and installed in the center of one of the containers 12. By moving the rods 19 of the hydraulic cylinders 17, the spreader 20 is lowered onto container. After the spreader grabs the container 12 by moving the rods 19 of the hydraulic cylinders 17, the container is raised above the vehicle to a height sufficient to install the container on the supports 4 and 5. By moving the rod 14 of the hydraulic cylinder 15, the lower face 18 of the deflection mechanism 13 together with the container is diverted (deflected) horizontally by a distance sufficient to turn the container around without interfering with the adjacent container. By turning the mechanism 8, the container is turned 90 ^° , the rod 14 is returned horizontally to its original position relative to the center of rotation of the mechanism 8, and the rods 19 of the hydraulic cylinders 17 are mounted on the supports 4 and 5. The hydraulic cylinders are lowered in pairs at different heights, ensuring that the lower edge of the container doors is raised above ramp coating. The container is centered when installed on the supports using the guides 23 of the support 5. After installing the container and opening its doors, the rods 22 of the hydraulic cylinders 21 of the support 4 are set to the lowest position, and the rods 22 of the hydraulic cylinders 21 of the support 5 are set to the required slope of the container: when unloading to the side of the ramp 3, and when loading to the side of the support 5. With the container mounted on the supports, it is released from the spreader locks, by the course of the rods 19 of the hydraulic cylinders 17, the spreader is lifted above the container and I turn the mechanism 8 t in the initial state. Then, the freight trolley 7 on the wheels 25 is moved along the guides 26 (laid on the lower belt 27 of the span 2) in the direction of the second container. A second container perform all operations described for the first container, except for the operation from an adjacent container deviation, since adjacent container (first container) is deployed at the time of the vehicle 90 ^on and does not prevent rotation of the second container. At the first container freed from the spreader, doors 32 are opened, using the fact that their lower edges 33 at the upper position of the support 4 are higher than the coating level 30 of the ramp 3 and take them outside the end of the container. Then the end face of the container with the door using the hydraulic cylinder 21 is lowered onto the ramp, ensuring their rigid docking. The floor 31 of the container 12 is installed flush with the level of coverage 30 of the ramp. The gap between the floor of the container 31 and the covering 30 of the ramp is covered with a light portable bridge 28, which rests on the container floor 31 with one edge and the second on the covering 30 of the ramp 3. With the frame 29, the bridge 28 rests on the ledge of the container doorway 12. The container prepared for processing is unloaded from load or load one of the known progressive methods, for example, heavy packages 34 on special pallets formed on the entire height of the container, which are loaded into the container and unloaded from the container using Niemi transport device hovercraft container 35. Processing is performed by this method average over 12 min. At the end of the processing of the container, the bridge 28 is removed, the container by the movement of the hydraulic cylinders 21 of the support 4 is raised above the ramp, the doors 32 are closed. By this time, the freight cart is returned to the first (processed) container and the spreader 20 is engaged with it. Next, the container is lifted, turned 90 ^° in the opposite direction and mounted on the vehicle. After installation of the container on the vehicle trolley is moved to the second container, which by this time is ready for lifting, grab it spreader raise deflect from its axis of rotation without changing the vertical position of deploying at ^90, again deflect relative to its axis of rotation to the initial position and set on the vehicle next to the first. The total processing time for a vehicle with two containers is 20-25 minutes, which corresponds to the removal of two loaded containers from the vehicle and the installation of two empty containers (or vice versa). When three containers are placed on the platform, its processing time is 23-28 min, which is less than the time of removing three empty containers from the platform and installing three loaded containers on it. For processing a platform with three containers, the device is equipped with three pairs of supports 4 and 5. If the containers are fed for processing on railway platforms, then after processing the front platform, the train (train) is pulled along the ramp using a traction winch.

Claims (3)

 1. SYSTEM FOR PREPARING CONTAINERS FOR UNLOADING FROM VEHICLE, comprising a superstructure with a cargo trolley carrying a lifting mechanism connected with a spreader, a ramp located along the superstructure, characterized in that, in order to expand technological capabilities and increase productivity, it is equipped mounted on a trolley by a rotary mechanism on which a deflection mechanism is mounted, which is formed by an articulated parallelogram connected to the drive, on which the said mechanism is fixed ema, and ramp-mounted adjustable feet for the installation of the container.  2. The system according to claim 1, characterized in that the lifting mechanism is formed by four hydraulic cylinders, the body of each of which is mounted on a parallelogram, and the rods are pivotally connected to the spreader.  3. The system according to claim 1, characterized in that the drive of the deflection mechanism is formed by a hydraulic cylinder, the housing of which is pivotally connected by an arm to a rotary mechanism, and the rod with a parallelogram.

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