Pile driving apparatus

Description

[0001] This invention relates to a pile driving apparatus of the kind defined by the precharacterising features of claim 1.

[0002] Jack piling apparatus are usually confined to situations where piles must be driven into the ground and no significant vibration and noise is permitted. Several pile driving apparatuses have been proposed in the past. Several are discussed in "Pile Design and Construction Practice", third edition by M. J. Tomlinson, published in 1987.

[0003] Previously used jack piling apparatus employ the use of a jack which bears down directly onto the top of the pile to be driven into the ground. These systems are frequently referred to as "jack-in piling systems". These systems are mainly used for underpinning foundations, but owing to their relative complexity, are not competitive with conventional piling systems and so are seldom used in new pile foundation works.

[0004] One previously used jack piling apparatus involves inserting a jack between the foundation to be underpinned and the top of the pile to be driven into the ground. In this kind of system, the foundations themselves provide the reaction force to the jacking.

[0005] These jack piling apparatus are subject to many disadvantages. In particular, the set up and positioning of the pile, and mobilization of the Kentledge or ballast to provide the reaction is slow. Generally, a hydraulic jack is used which however, is restricted to shorter strokes. This means that extensive use of dolly sections is required, at least six times to jack down one section of the pile. Moreover short and stout pile sections must be used, which means that the apparatus is only really suitable for larger bearing capacity piles (such as 40 tonnes above working load). These apparatus are also disadvantageous in that the extension pile prodecure is slow, and the joining of consecutive piles together, frequently done by welding is inefficient. Such jack piling apparatuses can only install two pile positions per working day. This makes such jack-in piling systems uneconomical for extensive use even in the present pile foundation market.

[0006] A pile driving apparatus of the kind defined by the precharacterizing features of claim 1 is known from the US-A-4 555 090. This pile driving apparatus is used to drive fence posts into the ground, and the jacking force is transmitted to the side of the fence post by means of a clamping device in order to also be able to put out that post. The disadvantages referred above are also valid for this known piling apparatus.

[0007] Each of the piling apparatus described above do not allow to measure the pile resistance or bearing capacitiy directly during the driving procedure.

[0008] From the GB-A-2 028 902 a hydraulically powered attachment is known applying a driving force preferably in a vibratory or hammering action onto the top of a stake to be pressed into the ground or onto the top of logs or stakes to be split.

[0009] It is the object of the present invention to provide a pile driving apparatus of the kind defined by the precharacterizing of features of claim 1 allowing to measure the pile resistance directly during the driving procedure and insuring a long stroke of the jack.

[0010] This object is obtained by the characterizing features of claim 1. Advantages developments of the invention are defined by the subclaims.

[0011] The invention will now be further described by way of example with reference to the accompanying drawings, in which:

Figure 1 is a sectional plan view taken along the lines A-A (of Figure 2) of an embodiment of the present invention;

Figure 2 is a sectional side elevation taken along the lines B-B of Figure 1;

Figure 3 is a detailed sectional plan view of part of the embodiment of the present invention;

Figure 4 is a part sectional side elevational view of the embodiment taken along the lines B-B of Figure 3;

Figure 5 is a schematic view of an embodiment of the invention supported by a mobile base machine;

Figure 6 illustrates an embodiment of the invention mounted on a static base frame which is positioned using a mobile crane; and Figures 7a and 7b respectively show plan and side elevational views of a clip for clipping adjacent piles together.

[0012] Figures 1 and 2 illustrate an embodiment of the invention which comprises a base frame 1 having a platform 3 for supporting ballast or Kentledge 5. The base frame 1 is preferably constructed of steel sections or steel plates which are sufficiently stiff to prevent any significant distortions occurring when the reaction force is applied during pile installation.

[0013] The base frame 1 is equipped with a levelling device in the form of jacks 7 positioned at each corner thereof. Each jack 7 can be adjusted independently of one another so as to ensure that the base frame lies substantially horizontally, and in particular, to ensure that a pile 8 (see Figure 3) to be driven into the ground is vertical with respect to the ground.

[0014] The Kentledge or ballast may be weights totalling 40 tonnes. One 10 tonne weight 9 may be positioned at each corner of the base frame 1 above a jack 7.

[0015] The pile driving apparatus comprises a column 11 positioned substantially perpendicular with respect to the base frame 1, and supported in position by means of steel supports 13. Bracing members 15 are provided on the base frame 1 in order to enhance the stiffness of the apparatus.

[0016] The column 11 will be described in detail below with reference to Figures 3 and 4. At the top of the column 11 is provided a lifting point 17 which can be attached to the hook of, for example, a mobile crane thereby enabling positioning of the apparatus.

[0017] The apparatus includes a pile loading device which consists of a cradle arm 19 which is pivotally mounted at point 21 to the base frame 1, at the lower end of the column 11. A hydraulic jack 23 is positioned on the base frame 1 and comprises a hydraulic piston 25 which is connected to the cradle arm 19. The operation of the cradle arm will be discussed below.

[0018] Figures 3 and 4 illustrate the column 11 of the pile driving apparatus in more detail. The column 11 is constructed of a steel "H" profiled column which is of sufficient strength to transmit the reaction force from a jack means to the Kentledge. The jack means is in the form of a hydraulic cylinder 27 and a hydraulic piston 29. The hydraulic cylinder 27 is fixedly attached to the top end of one side of the column 11. This side of the column 11 forms a hydraulic jack compartment of the pile driving apparatus.

[0019] The other side of the column 11 forms the pile compartment 31 of the pile driving apparatus. The pile compartment 31 receives the pile 8 for driving into the ground.

[0020] A transmission means transmits the pile driving force from the hydraulic cylinder 27 to the pile 8 contained in the pile compartment 31. The transmission means comprises a jack thrust plate 33 onto which the driving load of the hydraulic piston 29 bears. The jack thrust plate 33 is rigidly connected to a transmission plate 35 by means of a shear plate 37 which is welded onto the transmission plate. The higher end of the transmission plate 35 is rigidly connected to a pile thrust plate 39 by means of another shear plate 41. The web portion 43 of the column 11 is provided with an elongate slit running along the longitudinal length thereof for accommodating the transmission plate 35 and for permitting the transmission plate to move along the length of the column 11. As can be seen from Figure 4, when the hydraulic piston 29 urges downwardly against the jack thrust plate 33 in the direction of arrow A, a corresponding downward thrust is transmitted via the transmission plate 35 to the pile thrust plate 39.

[0021] The configuration of transmission means is such that the hydraulic cylinder 27 and the hydraulic piston 29 can extend alongside the pile to be driven into the ground. Consequently, piles having a length substantially corresponding to the height of the column 11 may be driven into the ground with embodiments of the present invention.

[0022] In order to enhance the stiffness of the column 11, stiffener plates 45 are welded along the length of the web portion 43 of the column 11. In the hydraulic jack compartment of the column 11, there is provided a channel section 47 which acts as a guide for the transmission plate 35. The channel section 47 also reduces the possibility of the transmission means twisting within the slit formed in the web portion 43.

[0023] The pile thrust plate 39 has a cross-section which corresponds to the cross-section of the pile 8. This thrust plate 39 makes contact with the pile to be driven into the ground.

[0024] The hydraulic piston 29 is capable of extending to substantially half the length of the pile 8, thereby driving half the length of the pile into the ground in one stroke.

[0025] This embodiment is provided with the pile loading device which comprises the cradle arm 19 which is pivotally mounted at the point 21 to the base frame 1 at the lower end of the column 11. The operation of the pile loading device is as follows.

[0026] The cradle arm 19 is lowered, by means of the hydraulic jack 23 and piston 25, into a horizontal position as illustrated in Figure 2. The pile element 8 is then lifted and placed horizontally onto the cradle arm 19 either manually or by crane. The hydraulic jack piston 25 then retracts causing the cradle arm 19 to swing into a vertical position together with the pile element to be loaded into the pile compartment 31 of the column 11. A guide 49 is provided on the cradle arm 19 which ensures that the lowermost end of the pile element is correctly located above the correct position on the ground, or if the pile element is an extension pile, the adapter 49 ensures that the lowermost end of the pile extension accurately locates with the top of the pile element already driven into the ground.

[0027] The guide 49 may be adjusted to accommodate piles of different profiles and sizes.

[0028] Figure 5 illustrates the pile driving apparatus of the present embodiment mounted on a mobile base machine 50. The pile driving apparatus may be transported by the mobile base machine 50 as illustrated in Figure 5. The column 11 is supported on the mobile base machine 50 by means of a steel hollow section column 51 which is pivotally supported at a point 53 of the mobile base machine 50. The pile driving apparatus can be deployed by means of the hydraulic arm 55. During deployment, the mobile base machine 50 can be stabilized by means of a stability jack 57.

[0029] Figure 6 illustrates the pile driving apparatus mounted on a static base frame which is positioned using a mobile crane 52. The mobile crane also loads the Kentledge onto the base frame. The column 11 is suspended from the mobile crane 52 by means of a hook attached to the lifting point 17 of the column 11. The horizontal positioning of the base frame 1 can be controlled by means of a position control attachment 59 which can be controlled by the mobile crane 52.

[0030] The installation of piles by the embodiment of the invention will be described as follows.

[0031] The mobile base machine or crane may be capable of lifting a 10 tonne load. The bearing capacity of the pile may be 16 tonnes working load, and the pile length per element may be 5 metres. During installation, the column 11 and base frame 1 are first lifted into place and positioned over the desired location. The four 10 tonne Kentledge pieces are then lifted and placed into position on the base frame 1 to form the Kentledge. Levelling of the base frame 1 can then take place in order to ensure that the column 11 is vertical.

[0032] While this is being done, the cradle arm 19 is lowered to the horizontal position in order to receive the pile element. The hydraulic jack 23 and 25 then lifts the cradle arm 19 and pile element into the pile compartment 31, and the pile thrust plate 39 is located on the top end of the pile.

[0033] The hydraulic cylinder and piston 27 and 29 can then drive the pile element, via the indirect jacking force method of the invention until, for example, half of the pile element is driven into the ground. The hydraulic piston 29 can then be retracted to its original position when the loading of the pile took place. During retraction of the piston 29, the cradle arm 19 is again lowered to the horizontal position in order to receive a steel dolly. The cradle arm 19 then lifts the dolly (not shown) into the pile compartment 31 with the dolly end resting flat on the half embedded pile element.

[0034] The hydraulic piston 29 is then activated again and the dolly pushes the remaining half of the pile element downwards. The cradle arm 19 can then be used to remove the dolly and further extension pile elements can then be driven into the ground using the above procedure.

[0035] Once the required pile penetration or bearing capacity has been reached, any pile elements protruding from the ground can be cut by means of an appropriate special cutter. The Kentledge can then be unloaded from the base frame and the apparatus then lifted to another pile position for repeat procedures.

[0036] Adjacent ends of extension piles may be connected together by means of the "clip in" jointing system of the present invention. An example of such a jointing system will be described below.

[0037] Figures 7a and 7b illustrate an embodiment of clip-in jointing system according to the present invention. The jointing assembly comprises a substantially "V"-shaped or triangular shaped plate 61 having the same cross-section as the pile element to be driven into the ground. A recess 63 is formed on each of the three sides of the plate 61 for receiving a linking portion 65 of a substantially "U" or "C" shaped clip 67. A plate 69 is welded to the plate 61 at each of the recess points 63, and provides a channel 71 or hole for receiving a leg 73 of the clip 67. A bonding bar 75 is welded to each of the plates 69.

[0038] The end of the concrete pile is cast around the bonding bars 75 thereby securely bonding the plate 61 to the pile element.

[0039] Tensile stress resultants are transferred from the concrete pile element to the bonding bars 75 by interface bond. These stresses are in turn transferred through the channel shaped plate 69 and the V-shaped or triangular shaped plate 61 which have been welded to the bonding bars 75. Through contact stresses, the tensile stress resultants are transferred via the clip 67 to the adjacent pile end of similar construction.

[0040] For compressive stress resultants, these stresses are transferred through direct contact stresses between the V-shaped plate 61 of adjacent pile elements.

[0041] During installation of pile elements, as soon as the two pile elements have been positioned end to end, the two legs 73 of the clip 67 can be simply and easily inserted into the channels 71.

[0042] The clip 67 is slightly profiled during manufacture to provide a slight interference or press fit during insertion at the joint.

[0043] Three or more clips 67 are positioned in order to rigidly secure the pile end together thereby restraining relative movement therebetween in each of the 6 degrees of freedom (ie 3 rotations and 3 translations).

[0044] The advantages afforded by embodiments of the present invention can be contrasted with established jack-in pile systems as follows.

[0045] Existing jack-in pile systems are restricted to relatively short pile elements, typically of 0.76 to 1.2 metres in length owing to the ability of the pile element to be manoeuvred by human strength. This leads to a large number of joints being required to instal a pile. Embodiments of the invention enable the use of relatively long pile elements, typically 3 to 6 metres in length since the pile can be manipulated by the machinery instead of relying on human effort. Also, fewer joints are required.

[0046] Also in embodiments of the invention, moderate side dimensions of piles may be employed, for example, 100 mm to 200 mm, whereas in established systems 300 mm² precast concrete piles are used.

[0047] In existing systems, the existing foundation is often used to provide the reaction for the jacking forces. However, embodiments of the invention enable Kentledge to be placed on a mobile machine or on the base frame of the apparatus itself. The Kentledge can easily be moved to a new position where required, and is not restricted to the position of the existing foundations.

[0048] Embodiments of the invention are also advantageous in that they permit a long stroke of the jack, for example, 1.5 to 4 metres thereby enabling an entire pile element to be installed in two strokes. In contrast, conventional systems have a short jack stroke of, for example, 0.25 metres thereby requiring a multiple number of strokes required to install a single pile element.

[0049] Embodiments of the invention may incorporate the clip-in jointing system described hereinabove which enables the joints of adjacent piles to be established speedily. This contrasts with prior art arrangements wherein precast concrete elements are bonded together by inserting short steel bars into the longitudinal central hole, and subsequently grouting them with cement.

[0050] Embodiments of the present invention enable full use of the available headroom, the headroom corresponding substantially to the length of each pile element to be used. For example, a 3 metre length of pile element may be installed in the headroom of only 3.1 metres. This contrasts with the prior art in which working headroom is required to accommodate both the length of the pile element and the hydraulic jack plus any packing. For example, a working headroom of about 1.8 metres enables installation of only a 1.2 metre length of open-ended steel tube.

[0051] Another difficulty with prior art arrangements is that the hydraulic jack and packing must be removed before another pile element can be added to the previous element already jacked into the ground. The jack is then put into position. In contrast, in embodiments of the invention the hydraulic jack 27 and 29, remains in position until the entire pile is installed to a required depth or bearing capacity.

[0052] Prior art arrangements are restricted for use in underpinning existing foundations. However, embodiments of the invention make it competitive to be used for new building foundations. Embodiments of the invention are not only cheaper and faster when used for underpinning existing foundations, but they will find substantial use for new foundations and are not restricted to underpinning existing foundations.

[0053] Embodiments of the invention also enable the use of twin or multiple hydraulic jacks to be used for providing the jacking force.

Claims

1. A pile driving apparatus comprising

- a base frame (1) having means supporting the apparatus and means supporting ballast (5),

- a column (11) fixed at its lower end at least substantially vertically to the base frame (1) and being adapted to receive along its length on one side thereof a pile (8) to be driven,

- jack means (27, 29) consisting of a hydraulic cylinder (27) fixed to the top end of the column (11) and of a hydraulic piston (29), the jack means extending at least partially alongside the column (11) at the other side thereof and thrusting in a direction substantially parallel to but spaced apart from the longitudinal axis of the column (11) and

- transmission means (33, 35, 39) transmitting a steady and continuous pile driving force from the piston (29) via a slit running lengthwise the column onto the pile (8) to be driven,

characterized in that
the column (11) is "H"-profiled, with its one side forming a first compartment for the jack means (27, 29) and its other side forming a second compartment (31) for receiving the pile (8), and that the transmission means (33, 35, 39) comprise a jack thrust plate (33) onto which the piston (29) acts, and which is rigidly connected to a transmission plate (35) guided lengthwise in the first compartment and extending upwards, with the upper end of the transmission plate (35) being connected to a pile thrust plate (39) extending horizontally and urging onto the top end of the pile (8) thereby transmitting the pile driving force from the direction parallel to the longitudinal axis of the pile (8) onto said pile (8).

2. A pile driving apparatus according to claim 1, characterized in that the jack means (27, 29) is fixed to one end of the column (11) on the side of the column (11) which is opposite from the side receiving the pile (8).

3. A pile driving apparatus according to claim 1 or 2, characterized in that the piston (29) of the jack means (27, 29) is capable of pushing the first thrust member (33) along substantially half of the length of the column (11) in a single stroke, thereby permitting driving of the pile (8) in two strokes of the jack means (27, 29).

4. A pile driving apparatus according to claim 3, characterized by a levelling means (7) for levelling the base frame (1) ensuring the column (11) is at least substantially vertical.

5. A pile driving apparatus according to any of the claims 1 to 4, characterized by a pile loading device comprising an elongate cradle (19) which is pivotally connectable (at 21) to the apparatus so that the cradle (19) can be moved between horizontal and vertical positions, and a jack (23) for moving the cradle (19) about the pivotal point (21), wherein the cradle (19) is configured to receive a pile (8) when in the horizontal position, and to be moved into a vertical position by means of the jack (23) thereby enabling positioning of the pile (8) for driving into the ground.

6. A pile driving apparatus according to claim 5, characterized by means (49) for guiding the end of the pile (8) closest to the pivotal end of the cradle (19) for locating it with the exposed end of the previously driven pile.

Ansprüche

1. Pfahlrammvorrichtung mit

- einem Grundrahmen (1) mit Mitteln zum Abstützen der Vorrichtung und Mitteln zum Abstützen von Ausgleichsgewichten,

- einer Säule (11), die an ihrem unteren Ende zumindest im wesentlichen vertikal an dem Grundrahmen (1) befestigt und so ausgelegt ist, daß sie an ihr entlang an ihrer einen Seite einen einzurammenden Pfahl (8) aufnimmt,

- Rammitteln (27, 29), die aus einem Hydraulikzylinder (27), der an dem oberen Ende der Säule (11) befestigt ist und aus einem Hydraulikkolben (29) bestehen, wobei die Rammittel sich zumindest teilweise längs der Säule (11) an deren anderer Seite erstrecken und Schub in einer Richtung ausüben, die im wesentlichen parallel zu der Längsachse der Säule (11), jedoch von dieser beabstandet ist und

- Übertragungsmitteln (33, 35, 39), die eine stetige und kontinuierliche Pfahlrammkraft von dem Kolben (39) über einen Schlitz, der längs der Säule verläuft, auf den einzurammenden Pfahl (8) überträgt,

dadurch gekennzeichnet, daß

- die Säule (11) ein "H"-Profil hat, dessen eine Seite eine erste Kammer für die Rammittel (27, 29) und dessen zweite Seite eine zweite Kammer (31) zur Aufnahme des Pfahls (8) bildet, und

- daß die Übertragungsmittel (33, 35, 39) eine Rammschubplatte (33) umfassen, auf welche der Kolben (29) drückt, und die starr mit einer Übertragungsplatte (35) verbunden ist, die in Längsrichtung in der ersten Kammer geführt ist und sich nach oben erstreckt, wobei das obere Ende der Übertragungsplatte (35) mit einer Pfahlschubplatte (39) verbunden ist, die sich waagerecht erstreckt und auf das obere Ende des Pfahls (8) drückt, wodurch sie die Pfahlrammkraft von der Richtung parallel zu der Längsachse des Pfahls (8) auf den Pfahl (8) überträgt.

2. Pfahlrammvorrichtung nach Anspruch 1, dadurch gekennzeichnet, daß die Rammittel (27, 29) an einem Ende der Säule (11) auf derjenigen Seite derselben befestigt sind, die der den Pfahl (8) aufnehmenden Seite gegenüberliegt.

3. Pfahlrammvorrichtung nach Anspruch 1 oder 2, dadurch gekennzeichnet, daß der Kolben 29 der Rammittel (27, 29) in der Lage ist, das erste Schubmittel (33) in einem einzigen Hub längs im wesentlichen der halben Länge der Säule (11) zu drücken und es dadurch erlaubt, den Pfahl (8) mit zwei Hüben der Rammittel (27, 29) einzurammen.

4. Pfahlrammvorrichtung nach Anspruch 3, gekennzeichnet durch Nivelliermittel (7) für den Grundrahmen (1), die sicherstellen, daß die Säule (11) zumindest im wesentlichen vertikal ist.

5. Pfahlrammvorrichtung nach einem der Ansprüche 1 bis 4, gekennzeichnet durch eine Pfahlbeschickungsvorrichtung, die eine langgestreckte Aufnahme (19) umfaßt, die mit der Vorrichtung schwenkbar (bei 21) verbunden werden kann, so daß die Aufnahme (19) zwischen einer horizontalen und einer vertikalen Stellung beweglich ist, und eine Vorrichtung (23) zum Bewegen der Aufnahme (19) um den Drehpunkt (21), wobei die Aufnahme (19) so ausgebildet ist, daß sie in ihrer horizontalen Stellung einen Pfahl (8) aufnehmen kann und mittels der Vorrichtung (23) in eine vertikale Stellung gebracht werden kann, wodurch sie die Positionierung des Pfahls (8) zum Einrammen in den Untergrund ermöglicht.

6. Pfahlrammvorrichtung nach Anspruch 5, gekennzeichnet durch Mittel (49) zur Führung des dem schwenkbaren Ende der Aufnahme (19) zunächstliegenden Endes des Pfahls (8), um dieses Ende mit dem herausragenden Ende des zuvor eingerammten Pfahls in Flucht zu bringen.

Revendications

1. Appareil d'enfoncement de pilier comportant :

- un bâti de base (1) ayant des moyens destinés à supporter l'appareil et des moyens destinés à supporter du lest (5),

- une colonne (11) fixée à son extrémité inférieure au moins sensiblement verticalement sur le bâti de base (1) et qui est prévue pour recevoir suivant sa longueur et sur un côté un pilier (8) devant être enfoncé,

- des moyens formant vérin (27, 29) comprenant un cylindre hydraulique (27) fixé au sommet de la colonne (11) ainsi qu'un piston hydraulique (29), les moyens formant vérin s'étendant au moins partiellement le long de la colonne (11) au niveau de l'autre côté de celle-ci et appliquant une poussée suivant une direction sensiblement parallèle à l'axe longitudinal de la colonne (11) mais espacée de celui-ci, et

- des moyens de transmission (33, 35, 39) transmettant au pilier (8) devant être enfoncé une force de battage du pilier régulière et continue provenant du piston (29) par l'intermédiaire d'une fente s'étendant suivant la longueur de la colonne,

caractérisé en ce que
la colonne (11) a un profil en "H", avec son premier côté formant un premier compartiment pour les moyens formant vérin (27, 29) et son autre côté formant un deuxième compartiment (31) destiné à recevoir le pilier (8), et en ce que les moyens de transmission (33, 35, 39) comportent une plaque de poussée de vérin (33) sur laquelle agit le piston (29), et qui est reliée rigidement à une plaque de transmission (35) qui est guidée dans le sens de la longueur à l'intérieur du premier compartiment et qui s'étend vers le haut, l'extrémité supérieure de la plaque de transmission (35) étant reliée à une plaque de poussée de pilier (39) qui s'étend à l'horizontale et pousse sur l'extrémité supérieure du pilier (8), en transmettant ainsi audit pilier (8) la force de battage de pilier depuis la direction parallèle à l'axe longitudinal du pilier (8).

2. Appareil d'enfoncement de pilier selon la revendication 1, caractérisé en ce que les moyens formant vérin (27, 29) sont fixés à une extrémité de la colonne (11) sur le côté de la colonne (11) qui est opposé au côté recevant le pilier (8).

3. Appareil d'enfoncement de pilier selon la revendication 1 ou 2, caractérisé en ce que le piston (29) des moyens formant vérins (27, 29) est apte à pousser le premier élément de poussée (33) sensiblement sur la moitié de la longueur de la colonne (11) en une seule course, permettant ainsi l'enfoncement du pilier (8) en deux courses des moyens formant vérin (27, 29).

4. Appareil d'enfoncement de pilier selon la revendication 3, caractérisé par des moyens de mise à niveau (7) destinés à mettre de niveau le bâti de base (1) en assurant que la colonne (11) est au moins sensiblement verticale.

5. Appareil d'enfoncement de pilier selon l'une quelconque des revendications 1 à 4, caractérisé par un dispositif de chargement de pilier comportant un berceau allongé (19) qui peut être relié de façon pivotante (en 21) à l'appareil, de sorte que le berceau (19) peut être déplacé entre des positions horizontale et verticale, et un vérin (23) destiné à déplacer le berceau (19) autour du point de pivotement (21), le berceau (19) étant agencé de façon à recevoir un pilier (8) lorsqu'il est en position horizontale, et pour être déplacé jusqu'à une position verticale au moyen du vérin (23), permettant ainsi le positionnement du pilier (8) afin de l'enfoncer dans le sol.

6. Appareil d'enfoncement de pilier selon la revendication 5, caractérisé par des moyens (49) destinés à guider l'extrémité du pilier (8) la plus proche de l'extrémité de pivotement du berceau allongé (19) afin de la positionner avec l'extrémité exposée du pilier précédemment enfoncé.

Drawing