Patent Description:
In marine seismic exploration one or more seismic sources, typical air guns located in the sea, emits sound waves. The sound waves are reflected and refracted by the sea floor and interfaces between subsurface strata with different elastic properties, and amplitudes and arrival times of the various sound waves are sensed by seismic sensors and analysed to provide information about the subsurface. Two main techniques are used to sense the sound waves; one is to tow seismic streamers containing sensors typically including hydrophones behind a vessel slightly below the sea surface, the other is to deploy seismic nodes containing seismic sensors typically including hydrophones and geophones at the sea floor. This invention relates to the latter technique.

When seismic nodes are deployed at the sea floor, they are normally deployed in a rectangular grid. The distances between nodes along lines of the grid are typically between <NUM> and <NUM> metres, and the distances between the lines are typically between <NUM> and <NUM> metres. After the nodes have been deployed, air guns towed by a vessel are fired. Sound waves from the shots and sound waves reflected and refracted by the sea floor and the interfaces between the subsurface strata are sensed by the sensors of the nodes. The nodes may be connected by a cable for transfer of seismic data representing the sensed sound waves to a surface vessel. Alternatively, the nodes may be autonomous, i.e. the nodes are connected by a cable for mechanical connection only, or there is no connection at all between the nodes. If the nodes are autonomous, they must in addition to the seismic sensors also include an energy source, e.g. a battery, a recorder, and a memory for storing seismic data representing the reflected and refracted sound waves. After the firing of the air guns is finished, the autonomous nodes are retrieved to a vessel and the seismic data are transferred from the memories to a data storage unit for later analysis.

<CIT> describes a method for seismic survey by autonomous seismic nodes at a sea floor, comprising attaching the nodes to a rope, loading the rope with the nodes into a node deployer, lowering the node deployer into the sea, towing the node deployer above the sea floor, deploying the rope with the nodes at the sea floor, collecting seismic data by the nodes, retrieving the rope with the nodes from the sea floor, and unloading seismic data from the nodes. It further describes a node deployer for deploying a rope with seismic nodes at the sea floor, comprising a magazine for the rope with the nodes.

<CIT> describes a deployment and retrieval apparatus for ocean bottom seismic receivers, the apparatus being a remotely operated vehicle (ROV) having a carrier attached thereto and carrying a plurality of receivers. The carrier includes a frame in which is mounted a structure for seating and releasing the receivers. The structure includes one or more movable conveyors disposed to move receivers along a linear path relative to the frame in order to discharge and retrieve ocean bottom seismic receivers. Document <CIT> discloses a carrier for transporting seismic nodes to and from a sea floor, comprising an interior for storing the nodes during the transport, and means for moving the nodes into and out of the interior of the carrier.

The purpose of the invention is to provide a carrier for transporting seismic nodes between a vessel on a sea surface and a depth near or at a sea floor. The carrier shall enable transport of a large number of nodes, and enable cooperation with a tool for transferring nodes to and from the carrier, particularly from the carrier to the sea floor and from the sea floor to the carrier. A further purpose is to provide a method for loading seismic nodes into the carrier, and a method for unloading seismic nodes from the carrier. At least the invention shall provide an alternative to prior art. Features, advantages and further purposes of the invention and how they are achieved will appear from the description, the drawings and the claims.

The invention thus relates to a carrier for transporting seismic nodes to and from a sea floor as defined in claim <NUM>. The nodes are stored in the interior of the carrier. "The interior of the carrier" shall mean any place in the carrier not in the node transfer position. This enables storing a large number of nodes in the carrier. The nodes rest on the support, and the pushers push the nodes along the support, which enables moving each node in the carrier between the interior of the carrier and the node transfer position. The carrier may comprise a guide for guiding the nodes when they are pushed along the support. At the node transfer position, the node can be transferred between the carrier and the sea floor or any other place, e.g. the deck of a vessel. This transfer may be carried out manually or by a tool. The tool may be a manipulator arm or any means that can transfer the nodes, e.g. a deployment system or an arm with fewer degrees of freedom than a manipulator arm, maybe only translation along <NUM> or <NUM> axes. Thus, there is provided a compact carrier which enables transporting a large number of seismic nodes between a vessel on a sea surface and a depth near or at a sea floor, and which enables cooperation with a tool for transferring nodes to and from the carrier.

In one alternative the node transfer position is on a ramp outside the support. In another alternative the node transfer position is on the support.

Preferably the chain is positioned below the support, and the pushers extend above the support. In connection with the chain and support, "below" shall mean at a lower level than, and "above" shall mean at a higher level than, i.e. not necessarily directly under and over, respectively. In one alternative the pushers are spaced along the chain with a distance corresponding to a length of the node plus a clearance. This enables placing the nodes between the pushers, and the nodes can thereby push the nodes along the support. In another alternative, the pushers are adapted to push gripping portions of the nodes. Such gripping portions may be formed in the undersides of the nodes. Both alternatives provide a stable positioning of the nodes in the carrier with a reliable movement of the nodes within the carrier.

In one alternative the support is a longitudinal support, and one chain is situated on each side of and below the support, with the pushers extending above the support. The two chains may be driven by respective sprockets with a common drive shaft driven by the motor. The pushers can then be attached to both chains. The use of two chains provides a reliable and stable embodiment. In another alternative there are two longitudinal supports for each row of nodes, and the chain is situated between and below the supports, with the pushers extending above the supports. In this alternative there is only one chain, which may be more cost-effective than two chains.

The components for moving the nodes between the interior of the carrier and the node transfer position are arranged in magazines. Each magazine comprises at least the chain and sprocket for moving one row of nodes. The magazines are exchangeable. The carrier may be dockable to an ROV (Remotely Operated Vehicle). The carrier may be docked to the ROV by a conventional docking system, including probes and corresponding receptacles for mechanical attachment of the carrier, and plugs and sockets or other connectors for transfer of electric and/or hydraulic power and electric control signals. The carrier may be docked to the underside of the ROV, and a manipulator arm of the ROV may be used to transfer the nodes to and from the carrier. The carrier may be stackable and dockable to another carrier, and two or more carriers may then be stacked on top of each other. These two or more stacked carriers may then be docked to the ROV together, and electric and/or hydraulic power and electric control signals may be transferred between the carriers. This provides an efficient way of transporting the nodes between the sea surface and the sea floor.

The motor that drives the drive sprocket may be an electric motor. The motor may, however, be hydraulic, which may be favourable if hydraulic power is available from the ROV. Hydraulic power may be transferred from the ROV to the carrier by couplings for high pressure fluid forming part of the docking system.

An example not encompassed by the wordings of the claims also relates to a seismic node for acquiring seismic data at a sea floor, comprising sensors for seismic signals, a processor for the seismic signals, a recorder, a memory for storing data representing the seismic signals, and a power source. The node is to be transported between a vessel on a sea surface and a depth near or at the sea floor by a carrier. The node is adapted to use in the carrier of the invention. First and foremost, this adaption comprises adapting the shape and size of the node to fit into the carrier, for a placement on the support and pushing by the pushers.

The invention further relates to a method for loading seismic nodes into the carrier, comprising placing a node in a node transfer position; starting the chain to make a pusher push the node towards the interior of the carrier; stopping the chain when the node has moved a length corresponding to a length of the node plus the clearance; and repeating the above steps, causing the nodes to form a row between the interior of the carrier and the node transfer position. The placing of the node in the node transfer position may be carried out manually or by the above discussed tool, e.g. a manipulator arm. Further, as discussed above, the node transfer position may be on a ramp outside the support. In this case, the node is pushed onto the support. This may also be carried out manually or by the above discussed tool. Alternatively, the node transfer position may be on the support, and in this case, it is not required to push the node onto the support.

The invention also relates to a method for unloading seismic nodes from the carrier, wherein the nodes are stored on a support in a row between the interior of the carrier and a node transfer position. The method comprises starting the chain to make the pushers push the row of nodes towards the node transfer position; stopping the chain when a node has arrived at the node transfer position; removing the node from the node transfer position, which may be carried out manually or by the above discussed tool; and repeating the above steps.

A seismic survey using the invention may be carried out as follows: Nodes are loaded into the carrier on shore or at a vessel's deck. This loading may be done manually or by the above discussed tool. The nodes may be loaded into the magazines while the magazines are inside the carrier or outside the carrier, with a subsequent placing of the magazines into the carrier. The carrier is then brought to the sea floor, typically by docking the carrier to an ROV and lowering the ROV into the sea by a crane from the vessel and moving the ROV to the sea floor, where the nodes are unloaded from the carrier and placed on the sea floor by means of the above discussed tool. If required, the ROV with the carrier may be moved to the vessel's deck for another loading of nodes, and again moved to the sea floor for continued unloading and placing of nodes on the sea floor by the tool. Seismic data are then acquired by the nodes. The acquisition of seismic data may be passive, i.e. the seismic nodes sense and register natural and manmade sound and vibrations coming from all directions, or the nodes may sense and register sound and vibrations caused by firing of seismic sources. When the acquisition of seismic data has been completed, the nodes are picked up from the sea floor and loaded into the carrier by the above discussed tool, and the ROV with the carrier is moved to the sea surface and lifted onto the vessel's deck. The nodes are then unloaded from the carrier for a transfer of seismic data to a data storage unit. This unloading may take place at the vessel's deck or on shore, and may be done manually or by the above discussed tool. The nodes may be unloaded from the magazines while the magazines are inside the carrier or after the magazines have been removed from the carrier.

Some embodiments of the invention will now be described with reference to the accompanying drawings, in which:.

<FIG> illustrates a vessel <NUM> floating at a sea surface <NUM> of a sea <NUM>. An ROV <NUM> has been lowered into the sea <NUM> by means of a cable <NUM> from a crane <NUM>. A carrier <NUM> filled with seismic nodes is located underneath the ROV. The nodes were loaded into the carrier <NUM> at the vessel, and the carrier was then docked to the ROV before the ROV was lowered into the sea. After being lowered into the sea <NUM>, the ROV <NUM> is moved in downwards vertical direction <NUM> to a sea floor <NUM>.

<FIG> illustrates the ROV <NUM> after the movement to the sea floor <NUM>. The ROV is of a known kind, including a propulsion and positioning system, a manipulator arm <NUM>, a video camera, and lights. The ROV <NUM> may also include sensors, e.g. pressure sensors, positioning sensors and proximity sensors, and other equipment required to carry out its tasks. The ROV <NUM> is controlled by a control system which may be in the ROV or on the vessel, or partly in the ROV and partly on the vessel. An operator on the vessel controls the control system. The cable <NUM> transfers electric power and control signals from the vessel to the ROV, and video signals and sensor signals from the ROV to the vessel.

The carrier <NUM> is docked to the ROV by a not illustrated docking system, which includes probes and corresponding receptacles for mechanical attachment of the carrier, and plugs and sockets for transfer of electric power and electric control signals. There may also be hydraulic connectors for transfer of hydraulic power.

<FIG> is a closer view of the ROV and carrier of <FIG> seen from the front. The manipulator arm <NUM> is not illustrated in <FIG>. Five nodes <NUM> are located next to each other at the front of the ROV <NUM> and the carrier <NUM>. Each of these nodes <NUM> is an outer node or front node in a row of nodes extending between the front of the carrier <NUM> and an interior <NUM> of the carrier <NUM>, see <FIG>, for storing the nodes. A ramp <NUM> in front of the nodes <NUM> forms node transfer positions <NUM>, one for each row of nodes <NUM>, for transferring the nodes <NUM> to and from the carrier <NUM>. The rows of nodes <NUM> are movable in their longitudinal direction, which will be discussed with reference to <FIG>.

With further reference to <FIG>, the manipulator arm <NUM> is of a known kind, comprising links and joints and a gripping tool <NUM> which includes a suction cup with a controllable suction mechanism for gripping and releasing the nodes <NUM>. Alternatively, the gripping tool may include gripping fingers or any other means for gripping the nodes. For the purpose of being gripped, the nodes may have handles or other gripping portions. The gripping tool <NUM> can reach the nodes <NUM> in all the node transfer positions <NUM>.

The manipulator arm <NUM> can transfer nodes from the carrier <NUM> to the sea floor <NUM>. When doing that, the gripping tool <NUM> first grips a node <NUM> in the node transfer position <NUM>, as illustrated with node <NUM>' for the rightmost node transfer position <NUM> in <FIG>. The manipulator arm <NUM> then lifts the node from the node transfer position <NUM> and places it on the sea floor <NUM> and releases it, as illustrated with node <NUM>" in <FIG>. As nodes <NUM> are transferred from the node transfer positions <NUM>, new nodes <NUM> can be moved from the row of nodes to the node transfer positions <NUM>, which will be discussed in more detail with reference to <FIG>.

The manipulator arm <NUM> can also transfer nodes from the sea floor <NUM> to the carrier <NUM>. This is the reverse operation, i.e. the gripping tool <NUM> first grips the node <NUM>" on the sea floor <NUM>, then lifts it from the sea floor <NUM> to the node transfer position <NUM> and releases it. The node can then be moved from the node transfer position <NUM> to the row of nodes, which will be discussed in more detail with reference to <FIG>.

Each of the five rows of nodes are located in a magazine. Thus, the carrier <NUM> has five magazines with nodes. The magazines are placed in a frame <NUM> of the carrier <NUM>. The ramp <NUM> forming the node transfer positions <NUM> is part of the carrier, however, the ramp may be part of the magazine, i.e. each magazine may have its own ramp.

<FIG> illustrates an embodiment of an exchangeable magazine <NUM> for the nodes <NUM>. A portion of the structural parts is cut away for illustrative purposes. The magazine <NUM> is oriented in the position in which it is used in <FIG>, and references to "upper", "lower", "above", "below" and similar terms related to relative location, should be understood in this way, ref. downwards vertical direction <NUM>.

The magazine comprises two longitudinal side plates <NUM> held together and stiffened by structural members <NUM>. Two endless chains <NUM> extend substantially over the length of the magazine <NUM>, and have lower portions near a bottom of the magazine <NUM>, upper portions approximately in the middle of the magazine <NUM>, front portions arranged on respective free running sprockets <NUM> near a magazine front end <NUM>, and rear portions arranged on respective not illustrated drive sprockets near an opposite, not illustrated rear end of the magazine <NUM>. The free running sprockets <NUM> are rotatably mounted on an axle <NUM> extending between and attached to the side plates <NUM> of the magazine <NUM>. The drive sprockets are mounted on a not illustrated common drive shaft, which in turn is driven by a not illustrated electric or hydraulic motor.

A support <NUM> made of a plate or rail connected to the structural members <NUM> extends in the longitudinal direction of the magazine <NUM> between the chains <NUM>. The upper portions of the chains are located below the support <NUM>. Pushers <NUM> are attached to the chains <NUM> at intervals, and extend above the support <NUM>.

The nodes <NUM> are arranged in a row <NUM> and slidably carried on the support <NUM>, with a pusher <NUM> between each node <NUM>. The intervals between the pushers <NUM> correspond to the length of the nodes <NUM> plus a clearance. "The length of the nodes" means the outer dimension of each node in a longitudinal direction <NUM>, <NUM> of the magazine <NUM>. The clearance is as a minimum the distance required for a practical placement of the nodes <NUM> on the support <NUM>, and may be between <NUM> and <NUM>, typically <NUM>. In other words, the intervals between the pushers <NUM> are adapted to the nodes <NUM> and the way they are placed on the support <NUM>.

The row <NUM> of nodes extends in the longitudinal direction <NUM>, <NUM> of the magazine <NUM>, from its front end <NUM> to a location away from the front end in the interior <NUM> of the carrier <NUM>, see <FIG>. Since the pushers <NUM> are located between the nodes <NUM>, the pushers push the row <NUM> of nodes along the support <NUM> when the chains <NUM> are moved. When the motor driving the chain <NUM> is run in a first direction, the upper portion of the chain <NUM> moves inwards in direction <NUM>, and the pushers <NUM> push the row <NUM> of nodes <NUM> inwards along the support <NUM> towards the magazine rear end. When the motor driving the chain <NUM> is run in a second direction opposite the first direction, the upper portion of the chain <NUM> moves outwards in direction <NUM>, and the pushers <NUM> push the row <NUM> of nodes <NUM> outwards along the support <NUM> towards the magazine front end <NUM>.

Upper portions of the side plates <NUM> form guide plates <NUM> that keep the nodes <NUM> laterally in place in the row <NUM> and guide the nodes <NUM> during their movement in the magazine <NUM>. The guide plates <NUM> have top portions <NUM> bent in right angles towards the row <NUM> of nodes <NUM>. When the carrier <NUM> is on the sea floor <NUM>, and during lowering and raising of the carrier <NUM>, the nodes <NUM> will be kept in place on the support <NUM> by the gravitation acting in vertical direction <NUM>, see <FIG> and <FIG>. However, if the carrier <NUM> is undesirably tilted, the guide plates' top portions <NUM> prevent the nodes from moving perpendicularly off the support <NUM>, away from the support <NUM>. Openings <NUM> in the side plates <NUM> and openings <NUM> in the guide plates <NUM> reduce weight and allow flow-through of water.

<FIG> illustrates an alternative embodiment of both the magazine <NUM> and the nodes <NUM>. This magazine has similar longitudinal side plates <NUM>, structural members <NUM>, sprockets <NUM>, axle <NUM> and not illustrated drive sprockets and motor as the magazine in <FIG>. Like <FIG>, a row <NUM> of nodes <NUM> is slidably carried on a support <NUM> arranged between the chains <NUM>, i.e. one chain <NUM> is arranged on each side of the support <NUM>. Further, upper portions of the chains <NUM> are located below the support <NUM>, and pushers <NUM> attached to the chains <NUM> extend above the support <NUM>. The pushers <NUM> are, however, different. The pushers <NUM> of <FIG> are smaller and located with much smaller intervals than in <FIG>. The nodes are also different. The nodes generally have a square shape, which is insignificant to the invention. Further, the undersides of the nodes <NUM> have gripping portions formed by alternating cogs <NUM> and notches <NUM>. When the node <NUM> is placed on the support <NUM>, the pushers <NUM> enter the notches <NUM> and abut the cogs <NUM>, and when the chains <NUM> move, the pushers <NUM> thereby push the nodes <NUM>.

Further, unlike the magazine <NUM> of <FIG>, in the magazine of <FIG> the node transfer position <NUM> is on the support <NUM> in the magazine front end <NUM>. This means that the magazine of <FIG> can be used in a carrier <NUM> without the ramp <NUM>. There are no guide plates <NUM> with top portions <NUM> at the location for the node transfer position <NUM>, which enables a manipulator arm <NUM> to lift nodes <NUM> to and from the node transfer position <NUM> on the support <NUM>. Both the embodiment with the node transfer position <NUM> on the support <NUM> and the embodiment with the pushers <NUM> engaging gripping portions in the undersides of the nodes are shown in <FIG>. This does, however, not mean that these two embodiments are linked to each other.

When loading seismic nodes <NUM> into the carrier <NUM> with the magazine of <FIG>, the magazine is located adjacent the node transfer position <NUM> on the ramp <NUM>. The manipulator arm <NUM> places a node <NUM> in the node transfer position <NUM> on the ramp <NUM>, as discussed above. Assuming there initially are no nodes in the magazine <NUM>, there will be empty space on the support <NUM> at the magazine front end <NUM>. Further, it is assumed that the pushers <NUM> have a position and movement where they do not block the access to the support <NUM> from the node transfer position <NUM>. This can be achieved by the chains <NUM> being stopped and one pusher <NUM> being located at the sprockets <NUM> between and below the node transfer position <NUM> and the support <NUM>, and the next pusher being located a distance from the magazine front end <NUM>. The manipulator arm <NUM> then pushes the node <NUM> onto the support <NUM> at the magazine front end <NUM>. For this purpose, the manipulator arm <NUM> may use the gripping tool <NUM> or another suitable tool mounted on the manipulator arm. Alternatively, the manipulator arm <NUM> may initially place the node <NUM> partly on the support <NUM>, to ease the transfer of the node <NUM> from the node transfer position <NUM> to the support <NUM>. The chains <NUM> are started, and a pusher <NUM> contacts the node <NUM> and pushes it towards the interior <NUM> of the carrier <NUM>. The chains <NUM> may be started before the node <NUM> has been completely pushed onto the support <NUM>, to provide a smooth transfer of the node <NUM> from the node transfer position <NUM> to the support <NUM>. When the node <NUM> has moved a length corresponding to a length of the node <NUM> plus the clearance (the clearance is discussed above) the chains <NUM> are stopped. Then there will be an empty space on the support <NUM> at the magazine front end <NUM>, and the magazine is ready for receiving another node <NUM>. The manipulator arm <NUM> places another node <NUM> in the node transfer position <NUM>, and the above steps are repeated as long as desired. Consecutive transferred nodes <NUM> thereby form a row <NUM> starting in the node transfer position <NUM> and extending towards the interior <NUM> of the carrier <NUM>.

When loading seismic nodes <NUM> into the carrier <NUM> with the magazine of <FIG>, since the node transfer position <NUM> is on the support <NUM>, the ramp <NUM> in the carrier <NUM> may be dispensed with. The manipulator arm <NUM> places a node <NUM> directly in the node transfer position <NUM> on the support <NUM>. The magazine of <FIG> also shows the alternative with the pushers <NUM> engaging gripping portions in the undersides of the nodes <NUM>, and therefore, during placing of the node <NUM> on the support <NUM>, it must be ensured that the pushers <NUM> enter the notches <NUM>. For this purpose, the chain <NUM> with the pushers <NUM> may be moved simultaneously. In other respects, loading seismic nodes <NUM> into the carrier <NUM> with the magazine of <FIG> is the same as loading with the magazine of <FIG>.

In another not illustrated embodiment, the alternative with the pushers <NUM> engaging gripping portions in the undersides of the nodes <NUM> may be used together with the node transfer position <NUM> being located on the ramp <NUM>. In this case it may be advantageous to move the chains <NUM> when moving the nodes from the node transfer position to the support <NUM>, to ensure that the pushers <NUM> enter the notches <NUM>.

Unloading of seismic nodes from the carrier <NUM> is the same for both the magazine of <FIG> and <FIG>. It is assumed that the nodes <NUM> initially are stored on the support <NUM> in a row <NUM> between the interior <NUM> of the carrier <NUM> and the magazine front end <NUM>, with no node in the node transfer position <NUM>. The chain <NUM> is started and run in direction <NUM> to make the pushers <NUM> push the row <NUM> of nodes <NUM> towards the node transfer position <NUM>. The chain <NUM> is stopped when a node <NUM> has arrived at the node transfer position <NUM>. For the magazine of <FIG>, this means that the front node <NUM>, i.e. the node in the magazine front end <NUM>, is pushed off the support <NUM>, onto the ramp <NUM>. For the magazine of <FIG>, this means that the front node <NUM> stays on the support <NUM>. The node is then removed from the node transfer position <NUM> by means of the manipulator arm <NUM>. Then the chain <NUM> is started to bring a new node <NUM> to the node transfer position <NUM>, and the above process is repeated as long as desired.

The start/stop of the motor for the drive sprockets is controlled by the control system or the operator. For this purpose, a sensor which detects presence of a node <NUM> in the node transfer position <NUM> is in communication with the control system, and when unloading nodes from the carrier <NUM>, the motor for the drive sprockets may thereby be started automatically when the node transfer position <NUM> is empty. Alternatively, the operator may use a camera on the ROV to visually detect the presence of a node in the node transfer position <NUM>.

Desired weight distribution in the carrier <NUM> can be achieved by a suitable sequence of transfer of the nodes from the various node transfer positions <NUM> and suitable movement of the nodes <NUM> inside the carrier <NUM>. Further, some nodes may be kept in the rear portion of the magazine <NUM>, i.e. the interior <NUM> of the carrier.

Before deploying the nodes, when the carrier is on the vessel or on shore, the nodes will be loaded into the magazines, and the magazines will be placed in the carrier. Alternatively, the nodes may be loaded into the magazines while the magazines are in the carrier, by means of the pushers as described above. After retrieving the nodes, i.e. after the nodes have been picked up from the sea floor and placed in the magazines and the ROV with the carrier has been moved to the sea surface and lifted aboard the vessel, or possibly on shore, the magazines will be removed from the carrier, and the nodes will be unloaded from the magazines. Alternatively, the nodes may be unloaded from the magazines while the magazines are in the carrier, by means of the pushers as described above.

Claim 1:
A carrier (<NUM>) for transporting seismic nodes (<NUM>) to and from a sea floor (<NUM>), comprising an interior (<NUM>) for storing the seismic nodes (<NUM>) during transport, and means for moving the seismic nodes (<NUM>) into and out of the interior (<NUM>) of the carrier (<NUM>), comprising:
node transfer positions (<NUM>) for transferring the seismic nodes (<NUM>) to and from the carrier (<NUM>); and - supports (<NUM>), each for supporting the seismic nodes (<NUM>) in a row (<NUM>) between the interior (<NUM>) of the carrier (<NUM>) and a node transfer position (<NUM>);
characterized in that said carrier (<NUM>) further comprises exchangeable magazines (<NUM>) for the seismic nodes (<NUM>), each magazine comprising an endless driven chain (<NUM>) with pushers (<NUM>) for pushing a row (<NUM>) of seismic nodes (<NUM>), a sprocket (<NUM>) for driving the chain (<NUM>), and a motor for driving the sprocket (<NUM>).