The present invention relates to a multistaged telescope boom.
There is no restriction of the invention neither to any particular type of such telescope boom nor to any special use thereof, which may for instance be for moving loads, such as components for building work, or just for getting access to objects located on a high level, such as windows for cleaning purposes.
The number of arms of such a telescope boom is two or more, but may be arbitrary and is often in the range of five to ten.
That the hydraulic system “is designed to force the hydraulic unit” is here to be interpreted that there is no control unit ensuring that the cylinder chambers in question is successively filled or drained, but this is ensured by mechanical means, so that there is no possibility to obtain another way of operation, but the hydraulic units are “forced” to operate in this way.
The invention is not restricted to a telescope boom having all the hydraulic units operating fully sequentially, i.e. so that a cylinder does not start to extend before the cylinder belonging to the next inner arm has been fully extended and the cylinder does not start to retract before the cylinder belonging to the next outer arm has been fully retracted, but this shall at least be the case for the cylinders belonging to the two innermost arms. This means for example in the case of seven cylinders that the four belonging to the four innermost arms may be designed to operate in this way, whereas the three cylinders belonging to the three outermost arms have a non-fully sequential operation.
However, it is preferred to have all the hydraulic units operating fully sequentially. For a multistaged telescope boom having no such control of the sequence of extending and retracting of the arms the structure has to be over-dimensioned for ensuring that the boom will manage the worst loading case. This means that for taking care of structural safety the smaller arm should withstand maximum load derivate from short outreach, so the design thereof should be as strong as the bigger arms. Similar considerations have to be made for any structural member belonging to such a telescope boom. This leads to a very heavy structure and high costs of such a boom.
By instead forcing the hydraulic units to operate according to a sequence as defined in the introduction each arm and other structural members belonging to the boom may be designed for exactly the maximum load to be taken by that member only during such operation, so that the structure may be light and economic, also thanks to the possibility to reduce the size of the cylinders of the hydraulic units.
A multistaged telescope boom as defined in the introduction having a fully sequential operation is for example known through the European patent 0 566 720. In spite of the advantages described above of a telescope boom operating in this way this telescope boom has still some drawbacks. The cylinders of the different hydraulic units of this and also other telescope booms are not located on the longitudinal centre axis of the boom, but at a distance thereto in the transversal direction. The cylinders are normally located on top and aside the telescopic arms. Such locations create additional moments on said arms when the cylinders driving forces act thereupon. Friction forces are not the only forces creating such additional moments, but they are very important and cause under certain circumstances great problems, so that the discussion below will be restricted to friction forces, although they do not constitute the only problem. When an arm of such a telescope boom extends such friction forces are created between the arm extending and the members guiding this arm inside the arm next thereto in the horizontal direction as well as in the vertical direction. As the arm extends the overlay of the arms becomes smaller and the friction forces higher, and the cylinder in question has to be dimensioned to be able to overcome these forces for obtaining the extension. The additional forces needed for the extension as a consequence of the friction forces induces additional bending moments on the boom profiles including the telescopic arms. That effect is proportional to the magnitudes of said distance to the longitudinal centre axis of each telescopic arm. A multiplying effect happen at the boom tip position when several arms are extended, since the deformation resulting from the extension of the first arm has its effect on following arms carried thereby and so on. This means that due to said induced moments on the telescopic arms the telescope boom tip moves up or down and sideways in a magnitude which depends on total boom outreach and forces needed to move actual moving arms when extending or retracting operations start.
If a cylinder is for instance located above said boom centre axis it has to push as much as needed for among others overcome friction forces on extension sliders for extension, which means that the arm in question will be deflected “downwards” in a vertical plane and also laterally in a horizontal plane in case the cylinder is out of the vertical plane including said boom centre axis. The opposite will happen if the different cylinders have to retract the telescope boom.
It is obvious that this phenomena may be very disturbing under certain working conditions, such as when starting to retract or extend at a nearly full outreach of the boom when it is a part of a sky lift and a person stands in said sky lift on a high level, for instance for cleaning windows. Such vertical and especially lateral movements of the boom tip may then be very unpleasant. In other situations such movements may result in difficulties to carry out certain type of works at a high accuracy required or other problems.
The object of the present invention is to provide a multistaged telescope boom of the type defined in the introduction reducing the drawbacks described above of such booms already known.
This object is according to the invention obtained by providing such a multistaged telescope boom in which at least the hydraulic unit of said innermost arm is provided with an arrangement adapted to isolate the cylinder chamber of that first cylinder from communication with said hydraulic system when that cylinder is fully extended and re-establish said communication upon fully retraction of the cylinder next to said first cylinder.
This means that said multiplying effect with respect to the influence of friction forces between said first cylinder and the next cylinder will not occur, since once the first cylinder is fully extended it has no need to be active any longer to extend or retract, so that active forces only needs to be applied to the moving cylinder. This means for instance in the case of a higher number of hydraulic units all provided with a said first cylinder except for the one belonging to the outermost arm, that when the telescope boom is fully extended and the outermost arm is started to retract only the cylinder belonging to this arm pulls, so that vertical and/or lateral movement of the boom tip position due to friction forces will only emanate therefrom and be much smaller than for the prior art telescope boom. When the cylinder belonging to the outermost arm try to retract in the prior art multistaged telescope boom all cylinders pull and the boom tip position will swing to a large extent both vertically and laterally.
According to a preferred embodiment of the invention said arrangement is adapted to obtain said isolation by means located within the cylinder jacket of said first cylinder, which is preferred, since such means are then well protected within the cylinder jacket. It is then also preferred to influence hydraulic flow paths within the cylinder jacket of said first cylinder for isolating said cylinder chamber of said first cylinder.
According to a preferred embodiment of the invention said arrangement is adapted to obtain said isolation and re-establishment of communication by pieces of said hydraulic unit forced to move by the piston or parts moving therewith when reaching full extension of the first cylinder and fully retraction of said next cylinder, respectively. Accordingly, this means that no control is needed for obtaining said isolation of the cylinder chamber from the hydraulic system, but this will automatically be obtained by said piece moved by the piston of said first cylinder at the end of the stroke thereof. The same apply for said re-establishment of communication between said cylinder chamber and the hydraulic system, which will take place automatically when the piston of said next cylinder has been moved to the fully retracted position of that cylinder and by that moved a said piece for obtaining said re-establishment. Thus, there is no need of any complicated and costly control for obtaining this and no risk of any faulty operation as a consequence of failure of such a control.
According to another preferred embodiment of the invention said arrangement comprises a first member adapted to block a hydraulic supply line to said cylinder chamber of the first cylinder in the reverse direction when this cylinder reaches full extension and a second member adapted to divert the hydraulic flow from the supply line to said cylinder chamber to a line to the next cylinder when this cylinder reaches full extension. Said second member is preferably located within the cylinder jacket of said first cylinder and it may be adapted to divert said hydraulic flow downstream an inlet into said first cylinder, which is preferred, since the diversion of the hydraulic flow will then take place where it may not be accidentally influenced by outer means. Said first member then preferably comprises a check valve arranged in said hydraulic supply line to said cylinder chamber. This means that once a cylinder chamber has been completely filled it will be isolated and the hydraulic supply line will be connected to the next cylinder for extension thereof.
According to another preferred embodiment of the invention said second member is arranged to be mechanically controlled by means connecting to the piston for being controlled in dependence of the position of the piston, which reliably ensures that the next cylinder will not be connected to the hydraulic supply line before the cylinder chamber of said first cylinder has been completely filled and this cylinder completely extended.
According to a preferred embodiment of the invention constituting a further development of the embodiment last mentioned said second member comprises two pieces with openings to the hydraulic supply line to said first cylinder and to the line to the next cylinder, respectively, and said means is adapted to create a displacement of these pieces with respect to each other when the piston reaches the fully extended position for bringing said openings in an overlap and divert said hydraulic supply to the line to the next cylinder. Such a mutual displacement of said two pieces will reliably ensure a connection of said next cylinder to the hydraulic supply line when the piston of said first cylinder reaches the full extended position and not before.
According to another preferred embodiment of the invention said first cylinder comprises a pipe extending axially from the cylinder bottom through the cylinder chamber and into a hollow piston rod of the hydraulic unit, and the interior of the hollow piston rod communicates with said line to the next cylinder and said second member is adapted to connect the interior of the pipe and thereby the next cylinder to the hydraulic supply to the first cylinder upon fully extension of said first cylinder. This constitutes a simple way to pass said hydraulic supply to said next cylinder while isolating the cylinder chamber of the first cylinder therefrom.
According to another preferred embodiment of the invention said pipe is axially movable with respect to said cylinder bottom and in a rest state spring-biased into a position isolating the interior thereof from said hydraulic supply to the first cylinder, and mechanical means are arranged to move the pipe against said spring action by movement of the piston at the end of the extension movement of the first cylinder for connecting the interior of the pipe to said hydraulic supply to the first cylinder. This will reliably ensure that the next cylinder is not connected to said hydraulic supply to the first cylinder until the piston reaches the end of its movement for the extension of the first cylinder and then overcome said spring action. “Spring-biased” and “spring action” is to be interpreted broadly, and it has not to be a question of a physical spring, but any means having the same behaviour is conceivable, such as a slightly compressed rubber cushion or the like.
According to another preferred embodiment of the invention said arrangement comprises a third member spring-biased into a position closing an exhaust opening of the cylinder chamber of said first cylinder and a fourth member adapted to press said third member out of said closing position for exhausting hydraulic fluid from the cylinder chamber through control by the hydraulic unit comprising said next cylinder depending upon the arrival of the latter to the fully retracted state. With respect to “spring-biased” the same interpretation as for the previous embodiment shall apply. It is in this way reliably obtained that said first cylinder will not start to retract or even pull before said next cylinder has been fully retracted.
According to another preferred embodiment of the invention said third member and said exhaust opening are designed to gradually and/or step by step increase the cross section of a flow path from said cylinder chamber to the hydraulic system upon pressing by the fourth member of the third member further away from said closing position. This takes care of a problem that would arise if said exhaust opening is suddenly completely opened to communicate with said hydraulic system. In such a case a sudden expansion of hydraulic fluid would create an enormous flow peak which in turn results in a pressure peak inside the first cylinder, which disturbs pressure equilibrium of retracting cylinder and moving parts resulting in quick decelerations on moving masses, which in combination with components play produce noises in the form of big bangs. However, this behaviour is avoided by gradually and/or step by step increase the cross section of the flow path. In a particularly preferred embodiment said third member and said exhaust opening are designed, upon moving of the third member away from said closing position, to firstly connect said cylinder chamber with the hydraulic system through a first opening with a small cross section and when moved further through a second opening with a substantially larger cross section. By first establishing a connection through said first opening creating a nozzle between the cylinder chamber and the hydraulic system the cylinder chamber will be depressurized, so that noticeable peak flows from that chamber upon opening the free passage of hydraulic fluid through the second opening will be avoided thus avoiding acceleration/decelerations during the retracting operation. This will avoid the creation of said big bangs or other disturbing noises. The cross section of said first opening is advantageously ⅓- 1/20, preferably ⅕- 1/15 and most preferred ⅛- 1/12 of the cross section of said second opening.
It is preferred that there is a distance between said two openings resulting in a so called dead stroke of said third member upon connection through said first opening before connection through said second opening for obtaining said depressurization before the connection through the second opening is established.
According to another preferred embodiment of the invention said fourth member has at least one opening adapted to participate in forming a flow part from the cylinder chamber to said hydraulic system, and said first and second openings are preferably provided in said fourth member.
According to another preferred embodiment of the invention said first cylinder comprises a piece adapted to be mechanically hit by a member of the next cylinder in the end of a retraction movement thereof for causing said fourth member to press said third member out of said closing position. This ensures in a reliable way that the cylinder chamber of said first cylinder will be isolated from said hydraulic system until the next cylinder has been fully retracted.
According to another preferred embodiment of the invention said first cylinder and the next cylinder comprise an inlet port to the rear side of the respective piston for connection to said hydraulic system for applying a hydraulic pressure upon the piston for retracting the respective cylinder, and said inlet ports are connected in series with the one belonging to the innermost cylinder before the one belonging to the next cylinder. This ensures that said next cylinder will retract firstly and that said fourth member will be pressed against said third member during the entire retraction of said first cylinder.
According to another preferred embodiment of the invention said first cylinder comprises a pipe extending axially from the cylinder bottom through the cylinder chamber and into a hollow piston rod of the hydraulic unit, the interior of the pipe being adapted to communicate with the said hydraulic system, and said exhaust opening being adapted to connect said cylinder chamber to the interior of the pipe for connection to the hydraulic system therethrough. This constitutes a preferred way of draining said cylinder chamber of the first cylinder when this cylinder is retracted.
According to another preferred embodiment of the invention all hydraulic units except for the one belonging to the outermost arm have the above features of any of the embodiments according to the invention of the hydraulic unit belonging to the innermost arm, so that all hydraulic units are forced to operate fully sequentially for filling the cylinder chamber of one cylinder at the time from the hydraulic unit of the innermost arm to that of the outermost arm when extending the boom and draining the cylinder chambers of the hydraulic units in the opposite order when retracting the boom. The advantages of such a fully sequentially operating telescope boom appear clearly from the discussion above.
Further advantages and advantageous features of the invention appear from the following description.
With reference to the appended drawings, below follows a specific description of a multistaged telescope boom according to preferred embodiments of the invention.
In the drawings:
A multistaged telescope boom of the type according to the invention is schematically illustrated in
All the cylinders except for the one 12 belonging to the outermost arm have preferably the same design, which is schematically shown in
The cylinder is in
The cylinder also has a pipe 30 extending axially from the cylinder bottom 23 and further into a hollow piston rod communicating with the inlet 18 of the next cylinder. This pipe 30 is in a rest state shown in
It is illustrated in
The fully extended position of the cylinder is schematically illustrated in
All inlets 20 are as mentioned connected in series, so all cylinders will try to retract under fluid pressure needed to retract the “last extended” cylinder. This means that this fluid pressure will act upon rear wall surfaces 39 of the respective piston. The inbuilt pressures in the cylinder chambers of the cylinders fully extended will keep those cylinders in the fully extended position, so that only the last cylinder will retract.
Accordingly, it is necessary to open a communication channel between the cylinder chamber 27 and the inlet/outlet 18 for making it possible to retract a cylinder. This is achieved in the following way. When the retracting cylinder reaches a position close to its most retracted position a piece 40 (very schematically indicated in
The end of the pipe 42 has two openings, namely a first opening 43 of a small cross section located closest to said end and a second opening 44 with a much larger cross section located at a distance in the axial direction to the first one. This means that when the pipe 42 pushes the member 36 out of its contact with the bottom wall 38 hydraulic fluid from the cylinder chamber may flow through the first opening 43 creating a small nozzle and depressurizing the cylinder chamber (position according to
The piece 45 (see for example
The influence of the design of the telescope boom according to the invention, in the case of all cylinders except for the one belonging to the outermost arm provided with an arrangement adapted to isolate the cylinder chamber of the cylinder from communication with the hydraulic system when the cylinder is fully extended and re-establish said communication upon fully retraction of the cylinder next thereto, upon the behaviour of such a telescope boom will now be explained by means of
The lines R shows what happens for a telescope boom according to the prior art during retraction. If the last cylinder try to retract, but is still not retracting, all extension cylinders will pull and the telescope boom will change position from A to B. It is seen that the boom tip position will vary a lot, especially in the lateral direction causing a substantial so called side bending. However, in the case of a telescope boom according to the present invention only the moving cylinder pulls when retracting, since the cylinder chambers of all the other cylinders are isolated from the hydraulic system of the telescope boom, which means that the boom tip position will move from A to C when the last cylinder tries to retract, which constitutes a tremendous improvement with respect to the problems of deflection, especially lateral deflection.
A part of a cylinder in a telescope boom according to a second preferred embodiment of the invention is illustrated in
Furthermore, it is shown that the hole 46 firstly opened by the movement of the pipe 30 has a smaller cross section than the hole 46′ next thereto.
The design according to
However, this problem is avoided thanks to the design according to
The invention is of course not in any way restricted to the embodiment described above, but many possibilities to modifications thereof should be apparent to a person with ordinary skill in the art without departing from the basic idea of the invention as defined in the appended claims.
The shape and mutual proportions of parts of said first cylinder may of course be different than shown in the figures and vary within a broad range.
“Gradually and/or step by step” with respect to the increase of said flow path cross section may be obtained in many other ways than described above with reference to
Number | Date | Country | Kind |
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05102606 | Apr 2005 | EP | regional |
Number | Name | Date | Kind |
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5355769 | Kottke | Oct 1994 | A |
5501346 | Wimmer | Mar 1996 | A |
6536325 | Badia Ba | Mar 2003 | B2 |
Number | Date | Country |
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1172321 | Jan 2002 | EP |
9641764 | Dec 1996 | WO |
02093055 | Nov 2002 | WO |
Number | Date | Country | |
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20060249469 A1 | Nov 2006 | US |