Abstract:
The invention relates to a sea container that can be closed on all sides, comprising a base frame, which has four corner posts, a top-side frame, and a bottom-side frame construction, wherein the corner posts are rigidly connected to the top-side frame and to the bottom-side frame construction. The bottom-side frame construction has a bearing frame, wherein installations in the container are fastened to the bearing frame and the bearing frame has tie-down means for tying down and for absorbing forces acting horizontally. Thus the invention makes it possible to accommodate installations such as a deploying device for a trailling antenna in a sea container even though traditional sea containers are unsuitable therefor.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
       [0001]    The present invention is the US national stage under 35 U.S.C. §371 of International Application No. PCT/EP2012/053103, which was filed on Feb. 23, 2012 and which claims the priority of application DE 10 2011 000 950.7 filed on Feb. 25, 2011 the content of which (text, drawings and claims) is incorporated here by reference in its entirety. 
     
    
     FIELD 
       [0002]    The invention relates to a sea container that can be closed on all sides. 
       BACKGROUND 
       [0003]    Generally, sea containers comprise a basic frame which has four corner posts, a top-side frame and a bottom-side frame structure, the corner posts being fixedly connected to the top-side frame and the bottom-side frame structure. 
         [0004]    Corner fittings on the bottom-side frame structure typically serve for positioning containers on mounting points provided on the deck of a vessel. Corner fittings on the top-side frame also serve for receiving lashing bars which are intended to prevent a container tipping over with the movement of the vessel. 
         [0005]    The mounting points in combination with the corner fittings prevent the container from slipping on-board a vessel. Such corner fittings as well as the mounting points, however, are only able to absorb horizontal forces to a very limited extent. 
         [0006]    It is conventionally not provided to deposit containers on the deck of a vessel outside such mounting points, as containers deposited in this manner are at risk of slipping which constitutes a danger for the vessel and the crew. 
       SUMMARY 
       [0007]    The object of the invention, therefore, is to increase the potential use of such known sea containers. 
         [0008]    The invention achieves this object by means of a sea container wherein the bottom-side frame structure comprises a bearing frame, installations in the container being fastened to the bearing frame and the bearing frame comprising lashing means for lashing down and for absorbing horizontally-acting forces. 
         [0009]    The invention thus permits heavy and large installations to be implemented in sea containers, the installations exerting tensile forces and/or torques onto the container from outside the container. The tensile forces and/or torques are introduced via the installations directly onto the bearing frame which is of robust configuration. The resulting forces can be transmitted from the bearing frame to the vessel via cables or chains. Thus, a stable structure, which is also able to absorb high tensile forces, is produced. Such high tensile forces can, for example, be produced when the installations comprise a winch mounted on the bearing frame for a trailing antenna of a sonar system or a deploying system, for example a crane mounted on the bearing frame, for underwater vessels or surface vessels or underwater moving bodies. Generally, containers are only used for transport or storage purposes. By means of the invention, however, there is also the possibility of using containers as part of mobile devices which are subjected to significantly greater forces and torques than containers provided simply for transport or storage purposes. 
         [0010]    By means of the invention, a container can also be deposited at a position on the deck of a vessel which has not been prepared for depositing containers. For example, therefore, a container can be deposited on a helicopter deck of a vessel, which conventionally does not have any mounting points for receiving corner fittings of the container. 
         [0011]    As a whole, therefore, a container according to the invention permits the potential use of sea containers to be substantially increased due to the additional bearing frame and the lashing means for receiving horizontally-acting forces. 
         [0012]    According to various embodiments, the bottom-side frame structure above the bearing frame comprises an upper bottom-side frame, which is welded to the bearing frame. The upper bottom-side frame comprises four corner fittings, two longitudinal members and two transverse members, the corner fittings in each case being connected fixedly to one end of one of the corner posts. 
         [0013]    In such a structure, a standard container can be used without the conventionally provided bottom wooden panels, the standard container being positioned on the bearing frame according to the invention and being welded thereto. The construction permits a cost-effective structure, as it is possible to use standard components of the container structure. In this case, however, the particular stress due to specific installations in the container does not have to be borne by the components of the standard container but simply by the specific structure of the bearing frame, which receives at least some of the mechanically demanding installations, such as winches, cranes and the like. In this case, the forces and torques introduced into the bearing frame do not enter the components of the standard container but are transmitted directly to the vessel via the lashing means. The components of a standard container thus remain unloaded and primarily serve for covering the top of the installations. The installations are thus able to be protected from environmental influences and unauthorised access. 
         [0014]    According to various embodiments, the bearing frame comprises four corner fittings at its corners as well as two longitudinal bearing frame members fixedly connected to the corner fittings and two transverse bearing frame members fixedly connected to the corner fittings. The lashing means are provided between one or more pairs of adjacent corner fittings of the bearing frame on one or both longitudinal bearing frame members and/or on one or both transverse bearing frame members. The container according to the invention thus comprises corner fittings in the bottom region thereof, notwithstanding the additional bearing frame, whereby the transport of the container can be effected by conventional trailers. Moreover, the additional receiving points permit the container to be deposited at normal container positioning points on-board a vessel. The corner fittings, however, are not available for receiving horizontal tensile forces as they are conventionally provided for lashing bars acting substantially perpendicularly and/or obliquely. Thus, between the corner fittings the lashing means are advantageously provided for horizontal lashing down and for receiving horizontally-acting forces. Advantageously, the lashing means are located in opposing positions, i.e. symmetrically to the longitudinal axis and/or transverse axis of the container, so that the lashing forces and the resulting mechanical stresses are able to be distributed uniformly over the bearing frame. 
         [0015]    In various embodiments, the bearing frame comprises transverse members which are arranged between the longitudinal bearing frame members and are fixedly connected thereto and to which at least some of the installations are fastened. Advantageously, a stable fastening is produced for heavy installations which may introduce large forces and torques into the container. In various embodiments, the aforementioned lashing means are provided in the region of the connection of the longitudinal bearing frame members to the transverse members. This reduces bending moments in the longitudinal bearing frame members. 
         [0016]    In various embodiments, the installations comprise a winch for a trailing antenna of a sonar system, a winch frame for receiving the winch being fastened to the bearing frame, in particular to two of the aforementioned transverse members. Advantageously, therefore, a mobile trailing antenna sonar system can be provided which can be used on merchant vessels, for example for protecting against pirates and/or for protecting a group of vessels, in particular merchant vessels and/or marine vessels. Merchant vessels generally do not have complex sonar systems for locating other vessels and/or boats, by means of which vessels or boats can also be located beyond the horizon. In particular, therefore, when detecting potential enemy vessels, in particular pirates, merchant vessels are often limited to a range as far as the visible horizon. In contrast, sonar systems have a considerably greater range. A merchant vessel is thus able to identify potential enemy vessels or boats even over a great distance and thus take suitable measures, including changing course or setting off an emergency signal. 
         [0017]    By means of the container according to the invention, therefore, trailing antenna sonar systems can be installed on-board virtually any vessel or other floating platforms or even on land, for example in the region of harbours, in particular on a quay, and even temporarily, for example when an area of the ocean subject to frequent pirate assaults has to be crossed. Moreover, larger groups of merchant vessels and/or marine vessels can be provided cost-effectively with trailing antenna sonar systems—even temporarily—which increases the safety of ocean navigation. 
         [0018]    In various embodiments, the installations comprise a deploying system for unmanned and/or manned underwater vessels and/or surface water vessels and/or underwater moving bodies for deploying such a vessel and/or underwater moving body in sea water, the deploying system being fastened to the bearing frame, in particular to two of the transverse members. Advantageously, therefore, a mobile deploying system can be provided for unmanned underwater vessels, in particular autonomous unmanned underwater vessels, but also remotely-controlled underwater vessels and unmanned surface water vessels but also for underwater moving bodies of any type. Such underwater vessels are, in particular, used in mine sweeping and/or mine clearance. By means of the invention, therefore, a mine sweeping and/or mine clearance system which is able to be deployed easily, is mobile and thus cost-effective, can also be provided. In particular, due to the invention such systems can also be accommodated on vessels not actually provided for the respective purpose so that the invention not only significantly increases the potential use of containers but also marine vessels as a whole. 
         [0019]    In various embodiments, the bearing frame comprises one or more floor panels for shielding the container interior from the surroundings on the bottom-side, the floor panel(s) comprising one or more draining means, in particular bilge plugs, bilge flaps and/or bilge pumps. Thus, in an advantageous manner, admitted sea water or rain water as well as condensation water can be easily discharged. In particular when retrieving a trailing antenna or a water vessel, sea water can regularly come on-board and thus enter the container. Due to the aforementioned draining means, the water can be easily removed again from the container. 
         [0020]    According to various embodiments, the container interior is divided into two by a partition and thus comprises a control room and a working space, the control room being hermetically sealed and/or being able to be hermetically sealed from the surroundings. The control room serves as a control station for one or more operators who have to perform their duties even in adverse environmental conditions over many hours or even days in the control room. The control room is thus intended to be equipped as comfortably as possible in order to be able to perform correctly a task requiring a high degree of concentration even in difficult weather conditions. Moreover, a hermetic seal also permits the protection of electronic components, in particular against moisture, and thus permits the use of many different types of electronic devices, such as for example conventional computer screens, printers, etc. in the control room. 
         [0021]    The working space is, in particular, provided for the aforementioned winch of a trailing antenna or, for example, for the deploying system for underwater vessels and/or surface water vessels as well as underwater moving bodies. A hermetic seal of the working space is not necessary as the working space is open during operation in any case and thus air is exchanged with the ambient air. 
         [0022]    In various embodiments, the control room comprises an access door, an emergency exit for leaving the control room in an emergency, a window to the working space, an air conditioning system, heat insulation for insulating the control room relative to the surroundings, a heating system, fire extinguishing means, first-aid means, a satellite telephone system, communication devices for communication, including data communication, with devices on-board the vessel accommodating the container and/or with devices outside the vessel, signal processing devices of a sonar system, electronic data processing devices, amongst other things, for processing, for example, sonar data, an emergency power supply, a satellite navigation system, for example a GPS (Global Positioning System) i.e. a satellite-assisted position locating system, an AIS i.e. an automatic identification system and/or further office equipment, such as chairs and tables. Thus, a control station fully equipped with all necessary devices is advantageously provided for round-the-clock use by personnel. 
         [0023]    In particular, in the case where the installations comprise a sonar system, the operation of such a sonar system requires a high degree of concentration on the part of the operator over many hours or days. Thus, extreme environmental conditions, for example at very low temperatures or very high temperatures and at a high level of air humidity, can be reduced to a tolerable level as far as possible. 
         [0024]    In a further advantageous embodiments, the installations comprise a voltage transformer for providing a predetermined and/or predeterminable initial voltage at variable input voltage. In various embodiments, the voltage transformer is accommodated in the working space. By means of a cable through-guide and/or a connection to the outside of the container, therefore, an external power supply can be connected to the container, the power supply not requiring any particular specification. Instead, the voltage transformer installed in the container ensures that the further electrical and electronic components inside the container receive the required electrical voltages. Thus, the container and, in particular, the installations thereof can be operated on many different types of vessel with different on-board power supply systems. The container according to the invention can be used and its installations can be operated even on a vessel without its own power supply, for example a sailing vessel. In this case, it would merely be required to connect an external power generator to the container. 
         [0025]    In various embodiments, the bottom-side frame structure, in particular the bearing frame, comprises external earthing points for the electrical earthing of the container. Due to the earthing points, it is possible to discharge even large electrical loads which can be produced for example by moving parts, such as a winch, or a malfunction, for example a short circuit. 
         [0026]    In various embodiments, the longitudinal members and/or transverse members of the basic frame, in particular of the upper bottom-side frame and/or the bearing frame, are provided as cable ducts. Such supports are often H-girders (I-girders), the transverse web thereof being arranged perpendicularly, or U-shaped girders. Thus, the H-girders and/or U-shaped girders provide the option of receiving cables. In this case, however, care has to be taken that the cables do not fall out of the hollow spaces of the H-girders and/or U-shaped girders. To this end, sealing elements are provided on the girders which partially seal the recesses externally, so that the region between the girders and the sealing element forms a cable guide. This is advantageous as “floating” cables are thus avoided in the region of the container. This increases the occupational safety, as the risk of tripping due to such “floating” cables is avoided. 
         [0027]    In various embodiments, the working space comprises an access door arranged on a side wall of the container, the container comprising a safety circuit which, when the access door is open, interrupts the electrical supply of an electrical drive in the working space, in particular of the winch and/or the deploying system and when the access door is closed, connects the electrical supply to the electrical drive. Thus, the risk of personnel entering the working space is avoided, as an opening of the access door automatically stops such drives. In this manner, the occupational safety is enhanced in the working space. 
         [0028]    In various embodiments, the access door of the control room and/or the access door of the working space is offset inwardly relative to the external dimensions of the container. Thus, it is ensured that even door handles or door locks of the access doors do not protrude beyond the external dimensions of the container and thus the container is able to be transported and stored in the manner of any other standard sea container. 
         [0029]    In various embodiments, the winch of the trailing antenna comprises a mechanical locking brake. Thus, even in the case of failure of the electrical power supply, the trailing antenna is prevented from unwinding in an uncontrolled manner. Moreover, however, even when deploying any length of trailing antenna, the winch can be stopped without further electrical power being required after the stopping thereof. 
         [0030]    In various embodiments, the winch comprises a slip ring for transmitting electrical and/or optical signals. This is advantageous, as trailing antennae of sonar systems already require an electrical power supply inside the trailing antenna to supply electro-acoustic transducers and for signal processing, and the sensor signals thus produced have to be transmitted from the trailing antenna into the data processing system of the sonar system. In various embodiments, this takes place by means of electrical and/or optical signals. The particular design of the winch permits the transport of the signals. 
         [0031]    In various embodiments, the winch comprises an impulse transmitter for determining the dispensed length of cable and/or trailing antenna, and a winch control unit which is configured such that, during operation of the winch, a minimum number of windings, for example at least three windings, of the tensioning cable remains on the winch drum. Such a minimum number of windings ensures traction relief in the region of the winch drum. 
     
    
     
       DRAWINGS 
         [0032]    Various embodiments are revealed from the claims as well as from the exemplary embodiments described in more detail with reference to the drawings. 
           [0033]      FIG. 1  shows a perspective view of a sea container that can be closed on all sides according to various exemplary embodiments of the invention. 
           [0034]      FIG. 2  shows a basic frame of the sea container according to  FIG. 1  in accordance with various embodiments of the invention. 
           [0035]      FIG. 3  shows a bearing frame of a basic frame according to  FIG. 2  with further details in accordance with various embodiments of the invention. 
           [0036]      FIG. 4  shows an enlarged detail A according to  FIG. 1  in the region of a corner fitting in accordance with various embodiments of the invention. 
           [0037]      FIG. 5  shows the sea container according to  FIG. 1  in a view from above to illustrate the position of the lashing means in accordance with various embodiments of the invention. 
           [0038]      FIG. 6  shows a side view of a sea container according to other exemplary embodiments of the invention. 
           [0039]      FIG. 7  shows a side view of the door side of the sea container according to  FIG. 6  in accordance with various embodiments of the invention. 
           [0040]      FIG. 8  shows a side view of the front face of the container according to  FIG. 6  in accordance with various embodiments of the invention. 
           [0041]      FIG. 9  shows a view from above of the sea container according to  FIG. 6  but with the roof cut open in accordance with various embodiments of the invention. 
           [0042]      FIG. 10  shows a side sectional view along the line X-X according to  FIG. 9  in accordance with various embodiments of the invention. 
           [0043]      FIG. 11  shows a view from above of the sea container according to  FIG. 6  in accordance with various embodiments of the invention. 
       
    
    
     DETAILED DESCRIPTION 
       [0044]      FIG. 1  shows a sea container  10  that can be closed on all sides and for this purpose comprises an access door  12  to a control room and an access door  14  for an working space, in which installations  16  fixedly installed in the sea container  10  are accommodated. The front face  18  on the rear side is able to be closed by means of a door, in particular a 2-leaf door (not shown). 
         [0045]    The top surface  20 , the side walls  22 ,  24 , the front wall  26  and optionally also the door surfaces in the region of the front face  18  on the rear side are made from profiled steel sheets and connected to a basic frame  28  which is described in more detail hereinafter in connection with  FIG. 2 . 
         [0046]    The installations  16  according to  FIG. 1  comprise an electrically-operated winch for receiving and deploying and retrieving a trailing antenna  30  of a sonar system. The trailing antenna has a tensioning cable having a length of several  100  metres as well as a portion with electro-acoustic transducers and an end section for stabilising and aligning the trailing antenna in the water. In particular, the acoustically relevant components of the trailing antenna have a diameter of approximately 5 to 10 cm. A trailing antenna which has been deployed, therefore, has a considerable flow resistance due to its length, its diameter as well as the end section, so that the aforementioned winch has to apply large tensile forces and/or is subjected to the tensile forces when the trailing antenna  30  is pulled along or is retrieved. The tensile forces, however, also act on the sea container  10 . Standard sea containers of a conventional type merely have wooden floors which are not suitable for fastening winches subjected to such high tensile forces, as the wooden floors would be ripped out of their anchoring points. Also, the remaining structure of such conventional sea containers is not designed to be subjected to the tensile force which occurs when deploying and/or retrieving such trailing antennae. 
         [0047]    The sea container  10  according to the invention, therefore, has a basic frame  28  which is reinforced relative to conventional sea containers and which comprises a top-side frame  32  with two top longitudinal members  34 ,  36  as well as two top transverse members  38 ,  40 . The basic frame  28  also has a bottom-side frame structure  42 , the bottom-side frame structure  42  and the top-side frame  32  being connected fixedly together, in particular welded, via the corner posts  44 ,  46 ,  48 ,  50 . 
         [0048]    The bottom-side frame structure  42  has a bearing frame  52 , at least some of the installations  16 , in particular the aforementioned winch, being fastened to the bearing frame  52 , and the bearing frame  52  additionally having lashing means  54 , shown for example in  FIGS. 1 and 4 , for lashing down and for receiving horizontally-acting forces. The lashing means  54  can be configured as eye-plates which are welded in longitudinal bearing frame members  56 ,  58  as well as transverse bearing frame members  60 ,  62 . 
         [0049]    The longitudinal bearing frame members  56 ,  58  and transverse bearing frame members  60 ,  62  can be configured as so-called H-girders and/or so-called I-girders. The aforementioned eye plates  54  are welded into the C-shape grooves of the longitudinal bearing frame members  56 ,  58  as well as transverse bearing frame members  60 ,  62 . The eye plates  54  have a recess, in particular a through-hole, for receiving a shackle. They are adapted to the contour of the H-girders and chamfered and welded to the girders by means of a fillet weld. 
         [0050]    The bearing frame  52  also has transverse members  64 ,  66 ,  68 , which in each case are arranged between the longitudinal bearing frame members  56 ,  58  and fixedly connected thereto, in particular welded thereto. The installations  16  can be connected to the transverse members  64 ,  66 ,  68 , so that forces which are introduced via the installations  16  are forwarded to the bearing frame  52  via the transverse members  64 ,  66 ,  68 , but without subjecting the structure of the basic frame  28  located above the bearing frame  52  to load in this case. The forces and/or torques introduced into the bearing frame  52  are directly introduced by the lashing means  54  into a vessel or a further offshore or land-based platform on which the container  10  is located. 
         [0051]    At its corners, the bearing frame  52  has corner fittings  70 ,  72 ,  74 ,  76  which are fixedly connected, in particular welded, to the longitudinal bearing frame members  56 ,  58  as well as the transverse bearing frame members  60 ,  62 . The corner fittings  70 ,  72 ,  74 ,  76  have eyes for receiving lashing bars as well as recesses and/or openings on the bottom for receiving mounting pins. 
         [0052]    The bottom-side frame structure  42  has a further frame above the bearing frame  52 , namely an upper bottom-side frame  78  which is welded to the bearing frame  52 . The upper bottom-side frame  78  is a component of a conventional sea container. It also has, therefore, four corner fittings  80 ,  82 ,  84 ,  86  which are configured in a similar manner to the corner fittings  70 ,  72 ,  74 ,  76 . The corner fittings  80 ,  82 ,  84 ,  86 , however, are not necessary due to the provision of the corner fittings  70 ,  72 ,  74 ,  76  and thus can be dispensed with in alternative embodiments. 
         [0053]    Moreover, the top-side frame  32  also has four corner fittings  88 ,  90 ,  92 ,  94 . The corner fittings  88 ,  90 ,  92 ,  94  are configured in a similar manner to the corner fittings  70 ,  72 ,  74 ,  76  and serve, in particular, for receiving lashing bars but also as anchoring points for a further container deposited on the sea container  10 . 
         [0054]    The upper bottom-side frame  78  has two longitudinal members  96 ,  98  as well as two transverse members  100 ,  102  between the corner fittings  80 ,  82 ,  84 ,  86 . Transverse beams  104 ,  106 ,  108  are attached between the longitudinal members  96 ,  98  of the upper bottom-side frame  78 , the beams serving to receive floor panels, in particular wooden panels, of the control room. 
         [0055]      FIG. 3  shows the bearing frame  52  with further details but without the frame structure located thereabove. The transverse members  64 ,  66 ,  68  separate the surface spanned by the longitudinal bearing frame members  56 ,  58  and the transverse bearing frame members  60 ,  62  into a plurality of partial surfaces. Each of the partial surfaces has a floor panel  110 ,  112 ,  114 ,  116 , which in each case on all sides is fully welded to the respectively surrounding longitudinal bearing frame members  56 ,  58  as well as the transverse bearing frame members  60 ,  62  and/or transverse members  64 ,  66 ,  68 . The floor panels  110 ,  112 ,  114 ,  116  are reinforced by reinforcements  118 ,  120 ,  122 ,  124 , advantageously configured as flat steel. 
         [0056]    One or more draining means, in particular bilge plugs, bilge flaps and/or bilge pumps are located in the region of one, several or all floor panels  110 ,  112 ,  114 ,  116 , in order to be able to discharge admitted sea water and/or rain water or condensation water. 
         [0057]      FIG. 4  shows the region around the corner fitting  70  in a detailed view. The longitudinal bearing frame member  56  is notched at the bottom in the region of the corner fitting  70 , so that the corner fitting  70  is fitted into this region. Two steel blocks  126 ,  128  are located above the corner fitting  70 , the steel blocks filling up the hollow space between the remaining end portion of the longitudinal bearing frame member  56  and the corner fitting  70 . The steel blocks  126 ,  128  are solid and adapted to the shape of the surrounding components, and welded thereto. 
         [0058]      FIG. 5  shows the sea container  10  in a view from above, the positions of the lashing means  54  being shown in more detail. In various embodiments, the positions are located symmetrically to the longitudinal axis and to the transverse axis of the container  10  so that the container  10  can be lashed down in the simplest possible manner to a flat deck without receiving points for corner fittings. Shackles can be arranged on the lashing means  54 , acted upon by tensioning cables or tensioning chains, which are secured to the deck of the vessel and/or the platform. The tensioning chains and/or tensioning cables do not have to run perpendicular to the bearing frame  52 . Angles ranging from +/−45 degrees to the vertical are permitted relative to the bearing frame  52 . 
         [0059]    The tensile forces exerted by the trailing antenna  30  on the bearing frame  52  are transmitted by means of the lashing means  54  to the deck of the vessel and/or the platform. The lashing means  54  are located on both longitudinal bearing frame members  56 ,  58  and on both transverse bearing frame members  60 ,  62 . 
         [0060]      FIGS. 6 to 11  show other exemplary embodiments according to the invention which corresponds substantially to the exemplary embodiments according to  FIGS. 1 to 5 , but the regions at the corners of the bearing frame  52 ′ according to  FIGS. 6 to 8  as well as  10  being configured differently. Moreover, the access doors  12 ′,  14 ′ additionally have windows. The features of the various exemplary embodiments, however, are able to be combined together individually or in any combination. 
         [0061]    All access doors  12 ,  14  and/or  12 ′,  14 ′ are watertight and fitted into recesses of the side wall, so that the doors  12 ,  12 ′,  14 ,  14 ′ including the door handles thereof do not protrude beyond the external dimensions of the sea container. 
         [0062]      FIGS. 6 ,  9  and  10  show a deploying device  130  for a trailing antenna, which comprises a winch  132  as well as a cable guide carriage  134  for controlled retrieving and deploying of the trailing antenna from the winch drum  136 . 
         [0063]    The deploying device  130  and/or the winch  132  further comprises an electric motor  138  for driving the winch drum  136 . The winch  132  also contains a slip ring for transmitting electrical and optical signals from the trailing antenna to the sonar data processing device  140  which is arranged in the control room  142 . 
         [0064]    The control room  142  is separated by means of a partition  144  from the working space  146 . The partition  144  comprises a window  148 . The window  148  permits the operator in the control room  142  to monitor the deploying device  130 . If visual monitoring is not possible via the window  148 , a camera is also provided in the region of the front face  18 ′ on the rear side which, in particular, is oriented toward the cable guide carriage  134 . A further camera in the region of the front face  18 ′ on the rear side is oriented out of the container in the direction of the surroundings, in order to be able to observe the path of the dispensed trailing antenna. 
         [0065]    During operation of the sonar system, i.e. when the trailing antenna is deployed, the 2-leaf door  150  is opened in the region of the front face  18 ′ on the rear side. The two door leafs are thus able to be fixed such that wind protection and spray water protection is provided by the door leafs. Additionally, the deployed door leafs  150 , optionally together with barrier grilles, prevent personnel from entering the region in which the trailing antenna is deployed. 
         [0066]    The winch drum  136  has two different drum diameters. A first smaller drum diameter serves for receiving the thinner but much longer tensioning cable which is provided with electrical and optical lines. A region of the winch drum  136  of greater diameter serves for receiving the acoustically effective antenna part. 
         [0067]    The cable guide carriage  134  determines onto which region of the winch drum  136  the respective trailing antenna portion is wound when retrieved. 
         [0068]    The sea container according to the invention thus permits a mobile deploying system for a trailing antenna of a sonar system. In this case, the sonar data processing device  140  can be arranged inside the container  140 , so that the container  140  shown accommodates a complete sonar system. The deploying device  130  has the purpose of reliably depositing the trailing antenna, together with the associated trailing cable, and receiving it again. The container  10 ,  10 ′ also provides the possibility of storing a trailing antenna in addition to the tensioning cable securely and to protect them during transport against damage, the effects of weather and access by unauthorised personnel. 
         [0069]    The control room  142  is able to be hermetically sealed against environmental influences so that the control room  142  is able to accommodate directly all the sensitive electronic devices of a sonar system. Thus, the installation cost on-board a vessel and/or any other platform when equipped with a trailing antenna sensor is reduced to a minimum. 
         [0070]    The electric motor  138  of the winch  132  is supplied via a central distributor. Moreover, the distributor supplies the lighting device, a heating device for protecting against condensation as well as an air conditioning system. The electrical connection of this distributor can take place via a three-phase supply, which is designed for voltages of 380 volts to 400 volts, a voltage transformer ensuring initial voltages of 230 volts and/or 115 volts. The initial voltage can be also provided as three-phase voltage. The container can have one or more earthing points on the bearing frame  52 ,  52 ′ for connecting to the electrical earthing of the vessel. 
         [0071]    Moreover, the container  10 ,  10 ′ has a watertight cable interconnection point. The interconnection point comprises various cable guide-through elements for the voltage supply as well as for data lines and optionally communication lines to the outside. The cables are deposited and/or positioned inside the container. All regions inside and outside the container  10 ,  10 ′ are able to be illuminated by means of lamps provided in the container  10 ,  10 ′, so that even in darkness sufficient light can be provided for operating the deploying device  130 . 
         [0072]    If the access door  14  and/or  14 ′ is opened, a safety circuit interrupts a winch operation which can be taking place, so that personnel are not at risk from the winch operation. 
         [0073]    The winch  132  is able to be operated steplessly in both rotational directions. It has a mechanical locking brake which, in particular in the event of failure of the electrical power supply, grips and secures the winch drum  136  in order to avoid uncontrolled unwinding of the trailing antenna. 
         [0074]    The winch  132  also contains an impulse transmitter which displays the dispensed length of the trailing antenna and/or the tensioning cable. The control of the winch  132  ensures that a minimum number of windings of the tensioning cable remains on the winch drum  136 , in order to provide thereby traction relief of the end of the cable. 
         [0075]    The winch  132  is able to be controlled in both directions from the control room  142 , in various embodiments by means of a joystick. 
         [0076]    The control room  142  is provided with all devices, including tables and chairs, which are required for lengthy operation of a sonar system. To this end, also included are an air conditioning system as well as heat insulation of the control room  142 , as well as fire extinguishers, first-aid means as well as an emergency exit on the front face and/or the wall opposing the access door  12 ,  12 ′ and/or in the top region. 
         [0077]    The sea container according to the invention has been described in connection with a trailing antenna sonar system. Such a container can, however, also be used for accommodating and for operating further sea-based systems, such as for example unmanned and/or manned underwater vessels and/or surface water vessels and/or underwater mobile bodies. The vessels as well as the aforementioned underwater mobile bodies require a deploying device, for example a crane, which is installed inside the container and in the event of operation can exert considerable torques and forces on the container. Such a crane is also fastened to the bearing frame  52 , so that the forces and torques exerted thereon are directly introduced into the bearing frame  52  and from there can be introduced via the lashing means  54  onto the vessel and/or the platform. 
         [0078]    By means of the container according to the invention, therefore, complex and expensive systems can be movably mounted and accommodated and operated directly from the container. This applies, in particular, to sonar systems but also to mine sweeping and/or mine clearance systems and other underwater moving bodies. 
         [0079]    All features cited in the above description of the figures, in the claims and in the introduction to the description are able to be used individually and in any combination. The disclosure of the invention is therefore not limited to the described and/or claimed combinations of features. On the contrary, all combinations of features should be considered as being disclosed.