An Alignment System for a Spreader
The invention relates to an alignment system for a spreader for lifting freight containers.
Conventionally, freight containers are lifted by engaging a lifting device known as a spreader to the top of the container. The spreader is connected to a crane by a lifting cable so that the crane can lift or lower the spreader. Spreaders are generally comprised of a metal frame having four pickup elements, commonly known as twistlocks located at each of the corners of the spreader. The twistlocks are adapted to engage with respective twistlock apertures in the top of the container and are rotated to lock the spreader to the container.
The operator of the crane is located in an operator's cabin which is located approximately 60 to 80 feet above the ground and is vertically above the spreader. Therefore, when an operator is attempting to align the spreader with the top of a container to engage the spreader with the container, the alignment procedure is difficult as the upper surface of the container with which the operator is trying to align the spreader is at least partially obscured by the spreader. Hence, the operator can not see the twistlock apertures or the twistlocks themselves.
Therefore, it is difficult for an operator to correctly align all four twistlocks with the respective twistlock apertures to engage the spreader with the container.
In accordance with a first aspect of the present invention, there is provided a spreader alignment system comprising an image capturing device adapted to be mounted on a spreader for lifting freight containers, a display device and a communication link to transmit an image captured by the image capturing device to the display device for display on the display device, the system also including an alignment reference mark for display on the display device.
In accordance with a second aspect of the present invention, there is provided a spreader alignment system comprising an image capturing device adapted to be mounted on a spreader for lifting freight containers, a processor and a communication link to transmit an image captured by the image capturing device to the processor, the processor comparing the captured image with a reference image and the processor being adapted to control relative movement of the spreader and container to until the captured image is within a predetermined deviation of the reference image.
In accordance with a third aspect of the present invention, a method of engaging a spreader with a freight container to be engaged by the spreader comprises causing relative movement between the spreader and the container until an image of a surface of the container including an alignment feature is captured by an image capturing device, and aligning the alignment feature with a reference image to align the spreader with the container, and engaging the spreader with the container.
In accordance with a fourth aspect of the present invention, there is provided a spreader for lifting freight containers, the spreader comprising a frame, four pickup elements mounted on the frame, an image capturing device mounted on the frame to capture an image of a surface portion of a container to be engaged by the spreader, the frame comprising four pickup element housings, one pickup element being located within each pickup element housing, and the image capturing device being located within one of the pickup element housings.
Preferably, the spreader comprises at least two image capturing devices, each image capturing device being located within a separate pickup element housing. Typically, where there are two image capturing devices, the image capturing devices are located in diagonally opposite pickup element housings.
If the spreader is a twinlift spreader which is adapted to lift two containers simultaneously, the spreader comprises four outer pickup element housings, with four respective outer pickup elements and four inner pickup element housings with four respective inner pickup elements, typically, four image capturing devices are provided. Preferably, each image capturing device is located in a respective outer pickup element housing.
In one example of the invention, the method may further comprise displaying the captured image on a display device, the reference image is an alignment reference mark, and the alignment feature is aligned with the alignment reference mark to align the spreader with the container.
In an alternative example of the invention, the captured image is compared with the reference image by a processor Typically, the processor causes relative movement between the spreader and the container until the captured image is within a predetermined deviation of the reference image to align the spreader with the container
Preferably, the display device is adapted to display all the images captured by the image capturing devices simultaneously and a reference alignment mark is displayed on the display device for each capturing device
Preferably, the alignment feature on the container is a pickup aperture to be engaged by a pickup element Typically, the pickup aperture forming the alignment feature is the pickup aperture corresponding to the pickup element adjacent the image capturing device
Preferably, the optical axis of the image capturing device is as close to the longitudinal axis of the adjacent pickup element as possible Typically, the optical axis of the image capturing device is substantially parallel with the longitudinal axis of the respective pickup element
Typically, the image capturing device may have a fixed focal length and the focal length is preferably approximately the distance from the image capturing device to the alignment feature immediately prior to engagement of the spreader with the respective container This has the advantage that an
operator has an indication of the distance of the pickup elements from the pickup apertures by the sharpness of the image of the alignment feature on the display device.
Preferably, the image capturing device is mounted on the frame by a mounting device which comprises shock absorption means.
The communication link may comprise a wire communication link or a wireless communication link.
An example of an alignment system for a spreader in accordance with the invention will now be described with reference to the accompanying drawings in which:
Figure 1 is a cross-sectional view through a twistlock element and twistlock element housing and a side view of a portion of a container prior to engagement of the twist lock element with the container; and Figure 2 shows a display device.
Figure 1 shows a container 1 having an upper corner piece 2 which includes a twistlock aperture (not shown) its upper surface. Above the container 1 is a twistlock element housing 3 which has a twist lock element 4 mounted within it. The twistlock element housing 3 forms part of the corner of a frame (not shown) of a spreader (not shown). In this particular example, the twistlock element
housing 3 comprises an inner housing 5 which is shdably movable within an outer housing 6
Mounted on the outer housing 6 is a bracket 7 which extends through an aperture in the side wall of the inner housing 5 and located within the inner housing 5 on the bracket 7 is a CCD camera 8 which faces an aperture 9 in a lower wall of the inner housing 5 The CCD camera 8 is placed such that the optical axis 10 of the CCD camera 8 is as close as possible to the longitudinal axis 11 of the twist lock element to minimise parallax errors
The components within the CCD camera 8 are mounted within the housing of the camera 8 on shock absorption mountings The shock absorption mountings help to minimise shocks on the camera components by, for example, the landing of the spreader on the container and from bumping of the spreader when the spreader is in use Also, the mounting of the cameras 8 on the outer housing 6, helps to isolate the cameras 8 from the landing of the spreader on container by virtue of the s dable movement between the inner housing 5 and outer housing 6 which acts as a shock absorption mechanism In addition, by locating the CCD camera 8 within the twist lock element housing 3, the CCD camera 8 is sheltered from the environment and therefore, less exposed to wind, sun and ram The CCD camera 8 is coupled to a display device 15 located in an operator's cabin in the crane by a wire communication system However, it is possible that the communication system between the CCD camera 8 and the display device 15 may comprise a wireless communication
Typically, for a spreader for lifting a single container, a CCD camera 8 may be located in two diagonally opposite twistlock element housings. However, it is possible that only one camera 8 may be used, that two or three cameras may be used in adjacent twistlock element housings, or that four cameras may be used such that there is a camera 8 located in each twistlock housing.
In the case of a twinlift spreader that lifts two containers in end to end relationship, such as shown in International (PCT) Patent Application No. WO 97/39973 or US Patent No 5,280,980, preferably, a camera 8 would be located in each of the four outer twistlock element housings. However, it is possible that the four cameras could be located in the four central twistlock element housings or in a combination of the central and outer twistlock element housings. It is also possible for a twinlift spreader that less than four cameras or more than four cameras may be used.
A typical display device 15 used by an operator while operating the spreader and crane is shown in Figure 2. The display device 15 has a screen 16 which is split into four quadrants 17, 18, 20, 21. Each quadrant 17, 18, 20, 21 has an alignment reference mark 19 marked in the centre of the quadrant.
Alternatively, to marking the reference alignment marks 19 on the screen, the alignment reference marks 19 may be marked on a lens of the cameras 8 so that it is displayed as part of the image captured by the cameras 8. In a further example, the alignment reference marks 19 may be generated by any other suitable means.
The image captured by each camera 8 is displayed on a respective quadrant 17, 18, 20, 21 of the screen 16. This enables an operator to view the image from each camera 8 simultaneously on the display device 15. If, for example, there are four cameras mounted on the spreader, there is one image form each camera 8 shown in each quadrant. If there is less than four cameras, for example, two cameras 8, only two of the quadrants 17, 18, 20, 21 will show images from the cameras 8. If there are more than four cameras 8, the images may be alternated on the quadrants either automatically or under the control of an operator. Alternatively, the screen may be split into more than four sections, or more than one display device may be provided.
The camera 8 generates a video signal which is sent to a processor (not shown) via a communication link that may be a wire communication link or a wireless communication link. The processor receives the video signals from all the cameras 8 and combines the video signals so that the display device displays one video signal in each quadrant.
In use, an operator manipulating a spreader identifies a container to be lifted using the spreader and lowers the spreader towards that container. As the spreader is lowered, the images from the two cameras 8 can be viewed by the operator on the respective quadrants 17, 18, 20, 21 and the operator aligns the alignment reference marks 19 with the respective alignment aperture located at the top of the corner section 2 of the container 1. In addition, if the camera 8 has a fixed focal length, the operator will have an indication of the separation of
the spreader and the container by how focused the image is in the quadrants 17, 18, 20, 21. As the spreader is lowered closer to the container 1 , the images of the alignment apertures in the quadrants 17, 18, 20, 21 will gradually come into focus.
Therefore, an operator is able to align the spreader with the container 1 by aligning the alignment apertures with the alignment reference marks 19 on display device 15 and having the spreader until the twistlock elements engage with the twistlock apertures while maintaining the images of the twistlock apertures aligned with the alignment reference marks 19.
In an alternative example to that described above, the processor may compare each image from the cameras 8 with a reference image of the alignment feature, for example a twistlock aperture, and the processor could control movement of the spreader automatically, without operator intervention, until the captured image from the cameras 8 is within a predetermined deviation of the reference image. The processor could then automatically align and engage the spreader with the container.
Further advantages of the invention are that by locating the camera 8 within the twist lock element housing, the camera 8 is sheltered from the environment and from the effects of wind, sun and rain. In addition, parallax effects are reduced as the camera 8 is relatively close to the longitudinal axis 11 of the twistlock element 4 which permits easier alignment of the spreader by the operator.