The invention concerns a crane trolley, particularly one with a short overall height. The invention is particularly useful with a single-rail trolley having a running gear frame having a hoisting mechanism, which can travel by running wheels on a rail. The invention is illustrated with a crane trolley having a lower flange of an essentially horizontally situated beam, with at least one running wheel being driven, and on the underside of the rail is arranged a friction roller interacting with the driven running wheel.
In crane trolleys with short overall height, in order to accomplish a compact and space-saving construction, the hoisting mechanism is arranged at the side, next to the beam carrying the rail, so that the actual load lifting tackle—the load hook—can be lifted as high as possible underneath the beam. This arrangement of the hoisting mechanism next to the beam produces an off-center position of the center of gravity of the running gear frame relative to the center of the beam. Due to this off-center shifting of the center of gravity, there is a risk when operating without a payload that the running wheels arranged on the rail, especially the lower flange of a beam, will lift up relative to the hoisting mechanism.
Such lifting should be avoided in order to prevent damage to the crane trolley and/or beam and avoid a slippage of the driven running wheels.
Various solutions are known from practice for solving this problem. One variant is to arrange a counterweight on the side of the running gear frame opposite the hoisting mechanism, so as displace the center of gravity back to the middle of the beam. A counterweight, on the one hand, takes up additional space, and on the other hand the proper weight of the crane trolley and the load on the beam is needlessly increased.
Generic crane trolleys are known from DE 42 09 565 C2 and EP 0 620 179 B1, in which a friction roller interacting with at least one driven running wheel is arranged on the underside of the lower flange. This likewise driven friction roller can be forced by a spring mechanism against the underside of the lower flange, in order to increase the traction of the driven running wheel.
These designs used in familiar driven friction rollers are often cumbersome and take up space, due to the drive unit of the friction roller. Furthermore, the wear behavior of the interacting driven running wheels and friction rollers is normally different, so that the rolling radii change in different ways, which again results in additional slippage of the less loaded wheel.
U.S. Pat. No. 3,212,455 discloses a single-rail crane trolley in which a friction roller can be adjusted on the underside of the traveling rail opposite a running wheel in order to prevent an undesirable tilting. By adjusting a screw, the friction roller can be swiveled in order to adjust the distance between the particular running roller and itself to prevent a tilting depending on the traveling rail.
The invention provides a crane trolley of the aforementioned kind, which ensures a reliable reduction of the slippage of the driven running wheel with a simple construction.
The solution to this problem is characterized, according to an aspect of the invention, in that a pair of friction rollers is provided, which can be adjusted on the underside of the traveling rail by adjusting the distance from each other with a common pressure mechanism.
Due to configuring the friction roller for increasing the traction as a non-driven friction roller pair, it is possible to make the friction roller design especially light and compact and thus space-saving, since a drive unit for the friction rollers has been eliminated.
In order to make sure that the friction roller pair ensures operation of the driven running wheel regardless of the direction of travel of the trolley, the two friction rollers of each pair of friction rollers may be arranged symmetrically to the axis of rotation of the particular running wheel underneath the running wheel, so that the two friction rollers of a pair of friction rollers always have the same radial load and ensure a uniform pressing of the running wheel against the lower flange of the beam, acting as the traveling rail.
According to one practical embodiment of the invention, it is proposed that each pair of friction rollers can be secured to the running gear frame by a support rod linkage, which preferably comprises two double-arm levers swiveling about a common axis, with a friction roller rotationally mounted at one free end of each lever. This scissors-like design of the support rod linkage is not only especially easy to produce, but also it is very flexible in use, since the distance between the two friction rollers of the pair can be adjusted relative to each other, so that the design can also be used regardless of the thickness of the rail, especially the thickness of the lower flange, and be adapted to it.
According to one embodiment of the invention, the other two free ends of the levers of the support rod linkage are joined together via a spring-loaded pressing mechanism, by which the position of the friction rollers of the pair and their pressing force against the underside of the rail, especially the lower flange, can be adjusted.
The pressing mechanism consists preferably of a screw joining together the two free ends of the levers and a pressure spring that can be placed on the screw and tightened by a nut. Besides the especially simple and economical design of this mechanism, it offers the possibility of adjusting the friction rollers continuously in broad limits and varying the pressing force by choice of the spring length and characteristics.
Furthermore, it is proposed that the support rod linkage of each pair of friction rollers can be fastened on a cross arm arranged on the running gear frame transverse to the direction of travel. Since the cross arms are preferably cross arms that join together the parts of the running gear frame arranged to the right and left of the beam, the installation of the support rod linkage carrying the pair of friction rollers requires no additional structural parts that would not be necessary if the pair of friction rollers were not installed.
According to a first embodiment of the invention, the positioning of the support rod linkage on the cross arm is done by a spacing tube which can be placed on the cross arm.
In a second embodiment of the invention, the support rod linkage is positioned precisely on the cross arm by a set collar which can be secured to the cross arm, for example, by means of a threaded pin or a stud screw.
Finally, it is proposed that a pair of non-driven friction rollers may be arranged underneath all running wheels, which are arranged in a row with the at least one driven running wheel in the direction of travel.
Further features and benefits of the invention are described by means of the enclosed drawings, which show two sample embodiments of the invented crane trolley only as examples.
Referring now to the drawings and the illustrative embodiments depicted therein, a crane trolley represented in front view and top view in
In order to be able to lift a load hook 6 via a cable pulley block 7 by means of the hoisting mechanism 1 as high as possible underneath the beam 4, the traveling mechanism frame 2 of the illustrated single-rail trolley has an especially low overall height. This low overall height is achieved in that the traveling mechanism frame 2 is formed from two frame pieces 2a and 2b, which are arranged on either side next to the beam 4. The two frame pieces 2a and 2b of the traveling mechanism frame 2 are joined rigidly together via cross arms 8 running transverse to the direction of travel of the trolley. The hoisting unit, consisting of a cable drum 1a of the hoisting mechanism 1 and a reeving part 9, which contains for example a cable end fastening, is arranged so that the load hook 6 guided on the cable pulley block 7 is positioned perpendicular beneath the vertical axis of the beam 4, in order to minimize strain on the beam 4.
Besides the represented use of a cable pulley block 7, it is of course also possible to operate the hoisting mechanism 1 with a chain pulley block.
The arrangement of the traveling mechanism frame 2 at the side next to the beam 4 produces a position of the center of gravity of the traveling mechanism frame 2 that is shifted off-center—relative to the middle of the beam 4—toward the frame piece 2a containing the hoisting mechanism 1. This displacement of the center of gravity can have the effect that, when the trolley is operating without payload, the running wheels 3 arranged opposite the hoisting mechanism 1 and especially the driven running wheel 3a will lift up and/or slip.
In order to prevent such a lifting or slippage, especially for the driven running wheel 3a, in the embodiment depicted there is arranged beneath the driven running wheel 3a a pair of friction rollers, consisting of two friction rollers 10, interacting with the driven running wheel 3a and resting against the underside 4b of the traveling rail, fashioned as a lower flange 4a. The construction and the mode of operation of the pair of friction rollers shall be explained more closely hereafter by
In order to stabilize the straight running of the trolley, four guide rollers 11 are furthermore mounted in the vicinity of the running wheels 3, 3a, able to turn about the vertical on the frame pieces 2a and 2b of the traveling mechanism frame 2, which thrust against the outer flanks 4c of the lower flange 4a of the beam 4, as can be seen in
The cross section representation of
In order to secure the linkage 12 on the traveling mechanism frame 2, the levers 14 have a borehole 15 in the region of the swivel axis 13, by which the linkage 12 can be pivoted on one of the cross arms 8, which join the two frame pieces 2a and 2b together. In the embodiment depicted, the linkage 12 is mounted on the front cross arm 8 in
The positioning of the linkage 12 on the cross arm 8 is an especially advantageous design, since no additional structural parts are required for the mounting of the linkage 12 that would not be necessary if the linkage 12 were omitted.
In order to bring the friction rollers 10 of the pair to bear against the underside 4b of the lower flange 4a and in this way also press the driven running wheel 3a by its running surface against the lower flange 4a, the free ends of the lever 14 placed opposite the friction rollers 10 are joined together by an adjusting mechanism, such as a pressing mechanism 16. Activating this pressing mechanism 16 brings about a mutual swiveling of the levers 14 relative to each other and thus an adjusting of the spacing between the friction rollers 10.
In the embodiment depicted in
According to the second embodiment depicted in
With the help of the spacer tube 17 or the set collar 18, the position of the support rod linkage 12 can be chosen freely according to the width B of the lower flange 4a of the beam 4, but it will preferably be adjusted so that the friction rollers 10 are arranged centrally beneath the driven running wheel 3a.
Besides using only one pair of friction rollers that is arranged exclusively beneath the driven running wheel 3a, it is also possible, of course, to arrange pairs of friction rollers beneath several running wheels 3, especially beneath all running wheels 3 on the part of the lower flange 4a of the beam 4 that lies opposite the frame piece 2a containing the hoisting mechanism 1, since these running wheels 3 have the greatest danger of lifting off and/or slipping because of the shifting of the center of gravity.
The adjustment of the friction rollers 10 of the pair using the pressing mechanism 16 is done as follows:
The friction rollers 10 bearing against the underside 4b of the lower flange 4a counteract the tendency of individual running wheels 3, 3a to lift off from the lower flange when operating without a payload, due to the shifting of the center of gravity of the traveling mechanism frame 2.
Depending on the mass of the trolley itself and the width B of the lower flange 4a of the beam 4, the compression spring 16b of the pressing mechanism 16 will be more or less loaded. By turning the nut 16c on the screw 16a, the compression spring 16b is further shortened until the driven running wheel 3a arranged above the support rod linkage 12 makes contact by its running surface with the lower flange 4a of the beam 4. This is the zero position of the radial load of the driven running wheel 3a.
Now, in order to produce a radial load on the driven running wheel 3a that is sufficient to propel the trolley without a payload and thus avoid a slippage, the compression spring 16b is further tightened until the driven running wheel 3a no longer slips upon acceleration of the traveling mechanism 5. In this position, the compression spring 16b of the pressing mechanism 16 still has sufficient distance from the maximum stress position to avoid a slippage by further tightening, even when the running surface of the lower flange 4a is wet or oily.
The length and characteristic of the compression spring 16b can be chosen so that the support rod linkage 12 and thus the pair of friction rollers can be adjusted to conventional flange thicknesses.
The above-specified crane trolley is distinguished in that the arrangement of the friction rollers is very compact, space-saving, and easily installed.
Furthermore, in combination with a frequency-regulated traveling mechanism 5, the run-up torque and thus the starting acceleration can be regulated and limited to a justifiable extent, which can considerably reduce the size of the radial load on the driven running wheel 3a as compared to solutions without frequency converter.
Changes and modifications in the specifically described embodiments can be carried out without departing from the principles of the invention which is intended to be limited only by the scope of the appended claims, as interpreted according to the principles of patent law including the doctrine of equivalents.
Number | Date | Country | Kind |
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103 45 102 | Sep 2003 | DE | national |
Number | Name | Date | Kind |
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3074354 | Wakkila | Jan 1963 | A |
3212455 | Workman | Oct 1965 | A |
3353503 | Pettit | Nov 1967 | A |
3854407 | Cocroft | Dec 1974 | A |
5213045 | Gersemsky | May 1993 | A |
5228961 | Sakai | Jul 1993 | A |
5419260 | Hamilton | May 1995 | A |
6840393 | Tu | Jan 2005 | B2 |
Number | Date | Country |
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0620179 | Jun 1998 | EP |
Number | Date | Country | |
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20050092201 A1 | May 2005 | US |