NL1021995C2 - Ram device, especially for driving piles, has ram block which is relatively low and wide - Google Patents

Abstract

The maximum width or cross-direction dimension of the ram block (2) is at least 1.5 times the maximum height of the block. Independent claims are also included for the following: (a) Ram device (1) for piles (3) or pile sections (3a, 3b) comprising a ram block and at least one resilient fitting (7) for transferring kinetic energy from the block to the pile, the fitting being located outside the drop region of the block and a system is provided for transferring kinetic energy from the block to the fitting and for transferring energy absorbed by the fitting to the block; and (b) Ram device for piles or pile sections comprising a ram block, optionally at least one resilient fitting for transferring kinetic energy from the block to the pile, and at least one hoist point (11) on the block or fitting for securing a wire, cable or the like to the block, this point being located in a lower position than the centre of gravity for the block and/or in an eccentric position relative to the block median.

Description

Short description: Piling device particularly suitable for piling with a limited available height.

The invention relates to a pile-driving device particularly suitable for pile-driving a pile or pile element at places where the available height is limited, comprising a pile-driving block with a certain largest height and a certain largest transverse dimension / width.

Such a pile-driving device is used for pile driving where a limited height is available, such as, for example, in basements of existing buildings and the like.

With such a pile driving method, the pile 10 to be driven is usually assembled from a number of pile elements that are successively driven into the ground. After a first pile element has largely been driven into the ground, a second pile element is attached to the first pile element, usually welded, and subsequently driven into the ground. This process is repeated until the desired pile depth is reached. Since welding or connecting two pile elements in a different way takes a relatively long time, it is advantageous to keep the pile elements as long as possible.

Furthermore, it is important to make the available fall height of the pile driver as large as possible because then a maximum amount of kinetic energy can be transferred to a pile (element). A higher possible energy transfer makes it possible to drive a pile (element) into the ground faster and / or to pile the pile into the ground at a greater depth.

In order to provide a large available fall height for the pile driver, while also relatively long pile elements can be driven into the ground, it has already been proposed to use a narrow cylindrical pile driver that can move in the hollow space of the pile and the kinetic built up during a fall. 30 can transfer energy to a baffle plate located in the hollow post.

A drawback of such a pile-driving device is that the (hollow) piles to be pile-driving must have a certain minimum diameter in order to make it possible to receive a pile-driving block of sufficient mass movably therein. Another drawback is that the piles to be driven must be hollow. As a result, it is not possible to drive relatively narrow and / or non-hollow piles into the ground efficiently.

The object of the invention is to provide an alternative pile-driving device suitable for pile-driving at a limited available height, wherein the available space located above a pile (element) I is utilized better.

According to a first aspect of the invention, the pile-driving device comprises a pile-driving pile whose largest transverse dimension / width H is at least 1.5 times, preferably at least 2 times the largest height of the pile-driving pile.

By providing a relatively low and wide piling block, the piling block takes up little space in the vertical direction, while it does have sufficient mass for effective pile driving (element).

Preferably, the pile driving device comprises a resilient element that transmits kinetic energy from the falling pile pile, spread over time, to the pile or pile element. By temporarily storing at least a portion of the kinetic energy in the resilient element, plastic deformation of the pile is prevented and therefore better use is made of the available kinetic energy.

In a first embodiment the resilient element is arranged between the pile or the pile element and the pile driver, wherein the pile driver is preferably provided with a recess, in which. The resilient element at least partially fits. By making it possible for the resilient element to fit into a recess in the pile driver, height is saved during pile-driving. The recess in the pile driver can advantageously be so deep that the resilient element can be received entirely in the pile driver. The recess can thereby be made so wide that it can also partially fall around the head of the pile element or pile element to be driven.

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The pile driver preferably has a contact portion with which kinetic energy is transferred from the pile driver directly or preferably via the resilient element to a post (element), the height of the pile driver above the contact portion 5 being at most 100 mm, preferably at most 50 mm and more preferably is a maximum of 20-40 mm. Such an embodiment takes a minimum amount of height, while the pile driver has sufficient strength.

According to a second aspect of the invention, the resilient element is located outside the fall range of the pile driver, wherein a construction is provided which is adapted to at least partially transfer kinetic energy from the pile driver to the resilient element and to enter into the resilient element transfer absorbed energy to the pole or the pole element. By the fall range of the pile driver is meant the area in which the pile driver can be located during pile-driving, i.e. the highest and lowest position of the pile driver and all positions in between.

By placing the resilient element in such a way, for the use of a resilient element it is only necessary to free up the height for the (spring) path traveled by the resilient element during a thrust of the pile driver. Since the resilient element is placed outside the space where the pile driver can be located, the length of the resilient element itself does not take up any space in the available vertical space.

A construction is then provided for transferring the kinetic energy of the pile driver at least partially to the resilient element and for temporarily transferring energy absorbed in the resilient element 30 to the pile or the pile element.

According to a third aspect of the invention, the pile driver or the resilient element comprises at least one hoisting point at which hoisting point a hoisting wire, hoisting chain or the like can be used for hoisting the pile block, wherein the hoisting point is lower than the center of gravity of the pile block and / or eccentric with respect to the center of gravity of the pile driver.

1 0219; I -4- I When lifting a pile driver it is necessary to provide a pulley or the like. Such a pulley occupies a certain vertical space which is necessary for turning the hoisting wire, hoisting chain or the like. By now providing the lifting point layer I 5 on the pile driver, for example below the center of gravity of the pile driver, it is possible to use a pulley, wherein the pile driver can also be hoisted very close to the ceiling of the room.

Since the impact surface of the pile driver, with which the kinetic energy is transferred directly or indirectly to the pile or the pile element, lies in the center of the pile driver, it is not advantageous to provide a lifting point there.

Therefore, a hoisting point is preferably arranged eccentrically, preferably outside the impact surface of the pile driver or the resilient element. The hoisting point is advantageously attached to the bottom and / or side of the pile driver or possibly the resilient element.

H By engaging the hoisting point is meant that the hoisting wire, hoisting chain or the like can transfer an upward force to the pile driver and / or the resilient element for hoisting it. For example, it is possible that at the hoisting point an end of the hoisting wire, hoisting chain or the like is attached to the pile driver or resilient element. It is also possible that the hoisting point is a guide, for instance a pulley, which guides the hoisting wire, hoisting chain or the like in such a way that the guide can transfer an upward force to the pile driver.

H The lifting point is advantageously arranged on the resilient element. The resilient element is usually lower than the pile driver, whereby the hoisting point is arranged as low as possible on the combination of the resilient element and the pile driver.

The pile driver and / or the resilient element advantageously has two or more hoisting points, each of which is connected to at least H a hoisting wire, hoisting chain or the like.

In a preferred embodiment, the pile driver has two H adjacent cable disks, rotatable about a horizontal axis, among others. preferably each on a side of the pile driver, so that the hoisting wire is, among others. runs horizontally through the pile driver and runs upwards on each side of the pile driver to a fixed attachment or a next cable disc or the like. which is supported stationarily, for example in the pile driving rig.

Advantageously, the pile-driving device comprises guide means for guiding the pile-driving block and the spring element possibly attached thereto during pile-driving. By using such guide means, the path covered by the pile driver during pile-driving can be determined with certainty. Moreover, by providing guide means, it is possible to provide only a single lifting point that is eccentric with respect to the center of gravity of the pile driver. In one embodiment, the guide means comprise one or more guide rods. The guide rods can, for example, run through guide holes or slots in the pile driver. Separate guide elements may also be provided on the pile driver that cooperate with the guide rods.

In another embodiment, the guide means comprise a connecting element which is fixedly attached to the pile driver or to the optionally attached resilient element with a first end and which is hinged to a fixed support with a second end. A kind of hinged construction is hereby obtained which ensures that the pile driver travels the intended fall trajectory during its fall, so that the pile driver lands correctly on the pile.

The height of the entire pile-driving device is preferably a maximum of 3.5 meters, more preferably a maximum of 2.5 meters.

Advantageously, a portion of the pile-driving device that extends above a pile or pile element to be driven into the ground, at the start of pile-driving of the pile or pile element, has a maximum height of 1.5 meters, preferably 1 meters and more preferably 0.75 meters. With the beginning of the pile driving it is meant that the pile or pile element is placed in the pile-driving device, wherein the pile element is possibly coupled to a pile element driven into the ground for this purpose, but that the pile or pile element is not yet 1021995 * I-6- I has not been partially introduced into the ground by dropping the pile driver onto the pile or the pile element.

The invention further relates to a method I according to claim 18 or 19.

The invention will be explained in more detail below with reference to two embodiments, wherein reference is made to the accompanying drawing. In this drawing: Fig. 1 shows a schematic representation of a first I embodiment of a pile-driving device according to the invention, Fig. 2 shows a schematic representation of a second embodiment of a pile-driving device according to the invention, and Fig. 3 a schematic representation of a third embodiment of a pile-driving device according to the invention.

Figure 1 schematically shows a first embodiment of the pile-driving device according to the invention, indicated in its entirety by reference numeral 1. The pile-driving device 1 comprises a pile-driving block 2, with which a pile 3 becomes in the ground 4. drive. Due to the presence of the obstruction 5, for example a ceiling in the basement of a building, the space available for piling is limited. The pile 3 therefore comprises a number of pile elements 3a, 3b, which are successively driven into the ground 4 with the pile-driving device 1. After driving a first pile element 3a, which is then largely in the ground, a second pile element 3b is placed thereon and coupled to the first pile element 3a. In the pile-driving device 1 shown, the first and the second pile element 3a, 3b are welded together with the weld 6. Alternatively, it is also possible to use an H-socket connection or the like.

After welding of the second pile element 3b, the H pile 3 is further driven into the ground to the desired depth, H is reached, whereby, if necessary, new pile elements (3c, H 3d, 3e, etc., not shown) on the pile each time. 3 can be welded.

H Because the obstruction 5 limits the height available H 35 when driving, it is important to use this height as well as possible, with the pile elements 3a, 3b used being as long as possible on the one hand, and the fall height of the pile driver 2 is as large as possible. The advantage of long pile elements 3a, 3b, etc. is that fewer pile elements need to be welded together to obtain the ultimately required pile length. This welding 5 is relatively difficult and therefore requires a lot of time.

A higher fall height is advantageous to transfer a maximum amount of kinetic energy to the post 3.

Due to a higher possible energy transfer, it is possible to drive the pile 3 into the ground faster and / or to pile the pile 3 into the ground 4 at a greater depth.

The pile driver 2 has a maximum width / diameter b-max and a maximum height h-max. In order to provide the pile driver with sufficient mass for the required kinetic energy on the one hand, and to occupy a minimal vertical space on the other, so that there is sufficient height for obtaining sufficient speed for the required kinetic energy, according to the invention the largest transverse dimension is width b-max of the pile driver at least 1.5 times the largest height h-max of the pile driver. According to the invention, the largest transverse dimension / width b-max is preferably at least twice the largest height h-max of the pile driver. For example, the pile driver has a horizontal dimension of 100 mm x 600 mm and a height of 333 mm, it is partly made of lead and has a mass of 2000 kg.

The pile-driving device 1 furthermore comprises a resilient element 7 which comprises an abutment surface 8, with which the assembly of the pile-driving block 2 and the resilient element 7 falls on a baffle plate 9 when it falls, said baffle plate 9 being arranged on top of the pile 3 . Hereby the kinetic energy that the assembly of the pile driver 2 and the resilient element 7 have built up during the fall is transferred to the baffle plate 9 and thus the pole 3. Due to the presence of the resilient element 7, part of the kinetic energy spread spread over time on the baffle plate 9, the kinetic energy being temporarily stored in the resilient element 7. This prevents plastic deformation of the pile and thus optimally 10. 19 9 3 “I -8- I made use of the kinetic H energy available through the fall.

In order to optimize the use of the available height, the resilient element 7 is advantageously arranged in a recess 10 provided in the pile block 2 for this purpose. In order to give the pile block 2 sufficient strength, the height of the pile is h-mid. pile driver 2 in the section above the recess 10 in the range between 10-100 mm, preferably 10-50 mm and more preferably 20-40 mm. These ranges are chosen such that the portion above the impact surface 8 is sufficiently strong to absorb the forces that occur during the transfer of the kinetic energy from the pile driver 2 to the pile 3, and has a minimum height, so that a large possible part of the available height remains for the fall height of the pile driver 2 and the length of the pile elements 3a, 3b to be used.

In an alternative embodiment it is also possible to arrange the resilient element 7 at the top of the pile, for example H on or on a pile-driving hat used during pile-driving, wherein the recess 10 during pile-driving at the end of the fall of the pile pile driver 2 falls around the resilient element 7.

The lifting device shown in Figure 1 has a single lifting point 11, to which a hoisting wire 12 is connected, which runs via a pulley 13 to a winch 14. The winch 14 comprises a motor with which the pile driver 2 can be lifted each time after a fall and subsequently dropping it onto the pile 3 again. In order to make it possible to hoist the pile driver as close as possible to the obstruction 5, the lifting point 11 is arranged eccentrically with respect to the center of gravity of the pile driver 2 and below the center of gravity of the pile driver 2. As a result, the pile driver 2 can be lifted completely against the obstruction 5, without this being limited by the presence of the pulley 13.

As already indicated earlier, the pile-driving device 1 comprises only a lifting point 11 on the lifting block 2, which lifting point 11 lies eccentrically with respect to and below the center of gravity of the driving block 2. In order to prevent the pile driver 2 from tipping over when it is being hoisted, guide means are provided for guiding the pile driver 2 during lifting and during fall, here in the form of two guide bars 15. The guide bars ensure that the pile driver pile driver 2 remains in its correct orientation during its lifting and falling. The guide bars 15 run through guide slots 16 which are provided in the pile driver 2 for this purpose. However, it is also possible to provide guide elements on the pile driver that cooperate with the guide bars 15 or other guide means.

In another embodiment, the guide means comprise a connecting element which is fixedly attached at one end to the pile driver or to the optionally attached resilient element 7 and hinged at a second end to a fixed support. Through such a connecting element, the path traveled by the pile driver 2 and the resilient element 7 attached thereto will describe a fixed path during the hoisting and falling thereof. It will be clear that the orientation of the pile driver 2 during the lifting and falling thereof will change due to the hinged connecting element. Optionally, it is also possible to combine such a hinged connecting element with other guide means, wherein optionally the connection of the hinged connecting element to the pile driver 2 and / or the resilient element 7 is also hinged.

In the embodiment of the device 1 according to the invention shown in Figure 1, two aspects of the present application are included. Firstly, a so-called "flat" pile driver 2 is provided, the largest transverse dimension / width b-max of which is at least 1.5 times the largest height h-max of the pile driver 2.

According to another aspect of the invention according to the present application, the pile driver 2 of the shown embodiment comprises a lifting point which is eccentric with respect to the center of gravity of the pile driver 2 and which, in the present case, is lower than the center of gravity of the pile driver 2. The advantages of arranging a hoisting point at such a location are that it is possible to lift the pile driver 2 upwards to the maximum and that the pulley 13 does not lift into the pile driver 2 when lifting the pile driver 2. away.

A further aspect of the invention will be explained with reference to Figure 2.

Figure 2 shows a second embodiment of a pile-driving device according to the invention, indicated in its entirety by the reference numeral 101. The pile-driving device shown comprises a pile-driving block 102, the largest of which is transverse dimension / width b-max. is at least 1.5, but preferably twice the highest height h-max of the pile driver 102. The pile-driving device 101 is used for the pile-driving of H a pile 103 which comprises the pile elements 103a and 103b, which pile elements 103a, 103b are welded together with the weld 106.

As with the embodiment of the pile-driving device according to the invention shown in figure 1, the pile 103 is built up of pile elements 3a, 3b, etc. to make it possible to pile a pile to a certain depth, despite the fact that the vertical space is limited by an existing obstruction 105, for example the ceiling of a basement or the like. Each time a next pile element has largely been driven into the ground 104, a next pile element can be welded onto the pile and subsequently driven into the soil 104.

The pile-driving device 101 comprises two lifting points 111 which are arranged on the bottom and outside of the pile-driving block 102. Connected to these hoisting points 111 are two hoisting cables, hoisting chains or the like, which are guided via the pulleys 113 to a winch 114 or the like in order to make it possible to lift and drop the pile driver 102 in each case. In the shown embodiment of the pile-driving device 101, the pulleys 113 lie in the path of the pile-driving block 102 and would in principle prevent the pile-driving pile 102 from being hoisted almost completely against the barrier 105. In order to make it possible to lift the pile driver 102 almost completely against the obstruction 105, two recesses 102a H are provided in the pile driver 102, which recesses 102a make it possible to receive the H pulleys 113 in the pile driver 102.

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To further save vertical space, the pile-driving device 101 comprises a construction with resilient elements 107, which resilient elements 107 serve, as in the embodiment of Figure 1, to transfer the kinetic energy of the pile-driving block 102 to the pile 103, so that a maximum amount of energy can be transferred to the pole 103 without it deforming plastically.

According to the said third aspect of the invention, the construction with resilient elements is embodied such that the two resilient elements 107 are outside the fall range of the pile driver. In the position shown of the pile driver 102 of the pile driving device 101 shown in Figure 2, the resilient elements 107 are located in this space, the resilient elements 107 being located below the pile driver 102.

The structure for transmitting the kinetic energy further comprises two structural elements 117 and 118. The structural element 118 has a portion on which the pile driver 102 can fall and the kinetic energy from the pile driver 102 can transfer to the resilient elements 107. The resilient elements 107 will store a portion of the transmitted kinetic energy from the pile driver 102 and transfer the remaining portion of the kinetic energy directly to the second structural element 117, which will thereby exert a thrust on the post 103. The structural element 117 takes over as it were the function of the baffle plate 9 of the embodiment of the pile-driving device 1 according to Figure 1. Due to the temporary storage of energy in the resilient elements 107, the kinetic energy of the pile driver 102 is transmitted over time over the pile 103.

The advantage of the embodiment of the construction with the resilient elements 107 and the construction elements 117, 118 is that the resilient elements are brought outside the fall path of the pile driver 102, so that only the vertical distance for the spring travel of the resilient elements 107 to be included in the available height 35. The length of the resilient elements 107 itself is placed outside the fall range of the pile driver 102, so that they in themselves have no influence on the intake of the limited vertical height available.

The construction with resilient elements 107 further comprises retaining means for retaining them. These means can for instance be formed by the cylindrical collar 119 shown in figure 2, which cylindrical collar 119 is complementary to the circumference of the pole 103, but it is of course also possible to extend these retaining means in a different way feed.

In the embodiment of the pile-driving device according to Figure 12, the structure with the resilient elements 107 is fixedly mounted on the post I 103, the pile-driving block being each time lifted and lowered onto the structure with the resilient elements 107. However, it is also possible to attach the construction with the resilient elements 107 to the pile driver, so that it moves with the pile driver 102 each time. In addition to the fact that the pile driving mass is slightly higher, this has the advantage that the structure with the resilient elements 107 does not have to be removed or reset in each case before and after the pile has been placed.

Figure 3 shows a pile driving block 40 according to the invention in vertical section. The pile driver 40 has two adjacent cable disks 41, 42, which are located next to each other and which are rotatable about a horizontal axis, each of which is arranged here on a side of the pile driver 40. A hoisting wire 43 runs over the cable pulleys 41, 42 with a horizontal part 44 which runs horizontally through the pile block 40 H. On each side of the pile driver 40, the hoisting wire 43 H has an upwardly extending part 46, 47, which in this example runs to an H cable cable 48, 49 following. In this example, the cable pulleys 48, 49 are supported by a frame 50 with two H stands. The hoisting wire 43 runs from each cable disc 48, 49 to a winch 51, 52. Thus, the pile driver 40 can be quickly raised and the available working height can be optimally utilized with a simple construction of the pile driver 40.

B

In the above-described embodiments of the hei-H device according to the invention, the various aspects of the invention have been highlighted in combination. It is also possible to use the various aspects of the invention separately or in other combinations in a remodeling device, in particular in a pile driving device in which the available vertical height is limited. Such embodiments are also considered to fall within the scope of the present patent (application).

1021 a -

Claims (21)

A pile-driving device particularly suitable for pile-driving a pile or pile element at places where the available height is limited, comprising a pile-driving block with a certain largest height and a certain largest transverse dimension / width, characterized in that the largest cross-section / width of the pile driver is at least 1.5 times the largest height of the pile driver. Piling device according to claim 1, characterized in that the largest transverse dimension / width of the pile driver is at least 2 times the largest height of the pile driver. 3. Pile driving device according to claim 1 or 2, characterized in that the pile driving device comprises at least one resilient element that is suitable for transferring kinetic energy from the pile driving block to a pile or pile element. 4. Piling device as claimed in claim 3, characterized in that the resilient element is arranged between the pile or the pile element and the pile driver, the pile driver being provided with a recess into which the resilient element at least partially fits. Piling device as claimed in claim 3, characterized in that the resilient element is outside the fall range of the pile driver, wherein a construction is provided which is adapted to at least partially transfer kinetic energy from the pile driver to the elastic element and to transfer energy absorbed in the resilient element 30 to the pole or pole element. 6. Piling device as claimed in one or more of the claims 1-5, characterized in that the pile driver has a contact part with which kinetic energy is transferred from the pile driver directly or preferably via the resilient element to a pile or pile element, wherein the height of the pile driver above the contact portion is 10-100 mm, preferably 10-50 mm, and more preferably 20-40 mm. Piling device as claimed in one or more of the claims 1-6, 5, characterized in that the pile driver or the resilient element comprises at least one hoisting point at which hoisting point a hoisting wire, hoisting chain or the like can engage for hoisting the pile block , where the lifting point is lower than the center of gravity of the pile driver. 10 8. Piling device as claimed in one or more of the claims 1-6, characterized in that the pile driver or the resilient element comprises at least one hoisting point at which hoisting point a hoisting wire, hoisting chain or the like can engage for hoisting the pile block , wherein the lifting point is eccentric with respect to the center of gravity of the pile driver. 9. Piling device as claimed in claim 7 and / or 8, characterized in that the lifting point is arranged on the resilient element. 10. Piling device as claimed in claim 7 and / or 8, characterized in that the pile driver and / or the resilient element comprises two or more hoisting points, each of which is connected to at least one hoisting wire, hoisting chain or the like. 11. Piling device as claimed in one or more of the claims 7-10, characterized in that the pile driver comprises a recess for at least partially receiving a hoisting pulley or the like therein near the highest position of the pile driver. 12. Piling device as claimed in one or more of the foregoing claims, characterized in that the pile driver has two adjacent cable discs, preferably each on a side of the pile driver, so that the hoisting wire runs horizontally through the pile driver and at each side of the pile driver goes upwards to a fixed attachment or a next cable disc that is supported stationary I, for example in the pile driver. Piling device as claimed in one or more of the claims 7-12, 5, characterized in that guide means are provided for guiding the pile driver and the spring element possibly attached thereto during the pile driving. 14. Piling device as claimed in claim 13, characterized in that the guide means comprise one or more guide rods. 15. Piling device as claimed in claim 13, characterized in that the guide means comprise a connecting element which is fixedly attached at one end to the pile driver or to the optionally attached resilient element and which is hinged at a second end to a fixed support applied. 16. Piling device particularly suitable for piling a pile or pile element at places where the available height is limited, comprising a pile driving block with a certain height and a certain transverse dimension / width, and at least one resilient element that is suitable transfer kinetic energy from the pile driver to a pile or pile element, characterized in that the resilient element is located outside the fall range of the pile driver H, wherein a structure is provided which is adapted to at least partially absorb kinetic energy from the pile driver to transfer to the resilient element and to transfer energy absorbed in the resilient element to the pole or the pole element. 17. Piling device particularly suitable for piling a pile or pile element at places where the available height is limited, comprising a pile driving block with a certain height and a certain transverse dimension / width, and optionally at least one resilient element suitable is to transfer kinetic energy from the pile driver to a pile or pile element, the pile driver or the resilient element comprising at least one lifting point at which lifting point can engage a hoisting wire, hoisting chain or the like for lifting the pile block with the characterized in that the lifting point is lower than the center of gravity of the pile driver 5 and / or is eccentric with respect to the center of gravity of the pile driver. Piling device according to one or more of the preceding claims, characterized in that the pile driving device has a height of at most 3.5 meters, preferably at most 2.5 meters. 19. Piling device as claimed in one or more of the foregoing claims, characterized in that a part of the pile driving device that extends above a pile or pile element to be driven into the ground, at the start of pile driving whether the pile element has a maximum height of 1.5 meters, preferably 1 meter and more preferably 0.75 meters. 20. Method for pile-driving at a limited available height, wherein use is made of a pile-driving device according to one or more of the preceding claims. 21. Method as claimed in claim 20, wherein the limited available height is a maximum of 3.5 meters, in particular a maximum of 2.5 meters. 1. o λ η n c