Patent Description:
During storage and transport of poultry (for instance on a poultry farm, from a poultry farm to another poultry farm, on a transport vehicle, from a poultry farm to a slaughterhouse or on a slaughterhouse) the poultry is usually held or transported alive in poultry holders. One such poultry holder is normally designed to hold plural animals in the order of magnitude of a dozen or several dozen of animals. These poultry holders are also referred to as "pallets", "crates", "cages" or "containers". For easy logistics a plurality of such poultry holders may be combined in a shared support structure that makes it possible to stack the poultry holders compact and to displace a support structure with the several holders as a single unit. A support structure may consist of a steel frame in which a number of poultry holders are held in stacked (multilayer) manner and from which the poultry holders can be wholly or partially removed, and can thus for instance be embodied such that they can slide optionally fully into and out of the support structure, similarly to drawers in a chest of drawers. Another possibility is to integrate the containers with the support structure so that this latter comprises compartments provided with individually controllable closing means.

Examples of poultry holders are known from the prior art. For example, European patent application published under number <CIT> discloses a method for filing a container with live poultry, wherein said container comprising compartments one on top of the other. Prior to the filling of a compartment with poultry, the bottom face of the compartment lying above it, together with the side face thereof, is moved away. Said side face is lying at the filling side of the container. The container is constructed in such a way that the poultry will meet no obstacles at the filling side above the compartment to be filled. Moving away said bottom and side faces may be performed by sliding them away sideways or by flapping them up.

European patent application published under number <CIT> discloses a poultry container and system for destacking, unloading and stacking poultry containers. The document discloses a combination of stackable poultry containers suitable for being loaded with poultry by manual or automated entrapment systems and for being transported in a stacked condition with substantially similar container. The document further discloses an apparatus for destacking a stack of several of the containers when loaded with poultry and restacking the containers when they are empty. The containers are generally rectangular, have open tops, and at least one wall which is hinged to pivot upwardly and inwardly during the loading of chickens into the container. The apparatus for destacking and restacking the containers includes a conveyor for carrying stacked or unstacked containers along a predetermined path of travel, a destacker for successively removing one container at a time from a stack of the containers, and a stacker for successively adding one container at a time to a stack of empty containers.

The <CIT> discloses a multiple cage stack construction for the transport of live animals. Each stacked compartment comprises at the front a hinged access door connected to a foldable compartment bottom part. The stacked compartments are held in their stacked position by a rigid chassis having a lower base and an upper element joined together by vertical uprights or bars. These uprights or bars are passing through orifices in the walls of the stacked compartments.

It is an object of the present invention to provide an alternative solution for combining plural poultry holders that enhances the poultry holding capacity/volume ratio and/or that enhances the weight/surface ratio of a number of stacked poultry holders. Furthermore it is an object of the invention to provide a solution for enhanced flexibility in the storage and transportation of live poultry.

The invention provides for this purpose a new and inventive container base, a container segment and a container assembly for holding live poultry composed from one or more container bases, one or more container segments and a container cover. In this respect the container assembly is a stack of a container base according the present invention on top of which container base one or more container segments, also according the present invention, are placed (stacked) and on the top container segment a cover may be placed to shield off the top container segment. In practise often use will be made of a container base, on top of which subsequently four (or five) container segments are placed and on the top of which container segments a cover is placed. However also larger or smaller assemblies may be applied. It is even possible to put together an assembly of a container base on which base are one or more container segments stacked where upon again a container base is stacked on top of which one or more subsequent container segments may be stacked of which the upper most container segment is carries the cover. For instance a practical stack-size for loading or unloading may be a base with four container segments while a transport facility (e.g. a truck) may allow to pile up two of such "five layered" assembles to result in a "ten layered" transport assembly configuration (including two container bases; one at the bottom and one at the sixth layer from below and carrying the cover on top). The flexibility of stacking enables to optimise various process wherein the container assemblies are used (e.g. loading, transporting, unloading, cleaning, storage and so on). As will be apparent from the subsequent description the stability of an assembly may be provided by the container base, which enables to choose for a lighter construction of the container segments.

The invention provides for this purpose a container base for holding live poultry, according to claim <NUM>. An advantage of such container base is that it makes a support for further poultry holders that provides strength so that one or more subsequent poultry holders (or as they will be addressed later in this description "container segments") to be stacked onto this container base can be of a lighter construction; the strength of the total construction may be provided for a substantial part by the container base thus the poultry holders on top of the container base may be of a lighter construction. A further advantage of the container base is that it pairs the ability of being stable and being handled by the forks of a fork-lift truck with the ability of holding live poultry between the sockets that are provided to feed the forks in. The container base according the present invention thus enhances the use of the available volume for the transportation of live poultry; except the volume that is required for the sockets and the further walls all the rest of the volume of the container base is utilised as poultry holding volume.

The sockets may be designed and dimensioned for the insertion of lifting forks. This enables handling of the container base according the invention with logistic equipment that is actually also available for handling prior art container bases. When the sockets are be constructed of metal this provides a solid construction that is useful in the rough conditions wherein the container bases are often used. However also alternative materials for constructing the sockets is an option, like for instance (reinforced) engineering plastics. To enable access to lifting forks from several sides of the container base the sockets may be provided with dual open ended sides and/or the second side walls may be formed by two parallel sockets.

The open ends (entrances) of the sockets may be provided with bevelled (chamfered) guide surfaces. The bevelled guide surfaces facilitate an easy entry of the lifting forks in the sockets. A bevelled guide surface on the entrance underside of the sockets has the additional advantage that the sockets are above the floor and will thus less pollute with dirt of the floor (like for instance poultry excrements). A bevelled guide surface on the entrance top of the sockets has the additional advantage that the lifting forks will less likely contact a container segment that is placed on top of the container base. Typically the height of the bevelled guide surfaces is <NUM> - <NUM>. Apart from bevelled guide surfaces on the underside and on the top of the sockets also bevelled guide surfaces may be provided on the sides (sidewalls) of the sockets. As to limit the top surfaces of the sockets carrying dirt also the top surfaces may be bevelled so to enable dirt on top of the sockets easy to remove or to slide off automatically.

The bottom wall has to be constructed such that it is a closed floor for the live poultry to be held, but apertures for ventilation and/or the passage of poultry droppings may be included. The top side of the container base may be opened (open top side) to enable live poultry to be loaded in the container base. Furthermore the height of all the side walls protruding from the bottom wall may correspond so to enable easy stacking of other items on top of the container base.

To even further enhance the ability of carrying items on top of the container base the side walls faces away from the bottom may be provided with a support edge for carrying items.

For ventilation purposes of the live poultry held by the container base the bottom wall and/or at least one of the side walls may be air permeable, which can be realised by providing one or more of the walls with apertures or a pattern of apertures. For efficient use of an available space (e.g. the transportation volume of a truck) the bottom surface of the container base may be substantial rectangular, which may be realised when the first and second side walls are perpendicular connected. Furthermore a substantial rectangular construction of side walls may be may advantageous. A further addition to the container base may be the provision of (low) legs to keep a substantial part of the container base free from the underground it is resting on. To enable easy and animal friendly loading of the container base one of the (longer) sidewalls may locally be lowered as will subsequently be explained in relation to the container segment according the present invention.

In a further embodiment of the container base the sidewalls may locally, more especially adjoining the corners of the container base, be provided with an inward set back wall parts. These inward set back wall parts may gradually sloping inward from the bottom, but the inward set back wall parts may also set back in a non-gradual configuration. The advantage of the inward set back wall parts is that they enable access to the underside of an element (e.g. a container segment) stacked onto the container base. Such easy access to the underside of an element facilitates easy stacking and unstacking of a container assembly as will be discussed in more detail below.

As to provide additional support to elements stacked onto a container base also additional support surfaces me be provided on the upper wall sides of the side walls of the container base.

The present invention also provides a container segment for holding live poultry according claim <NUM>. The door of the container segment according the present invention may also be used in circumstances wherein one or both of the sides of the container segment are resting against other items (e.g. another container segment). By opening the door, that means by bringing the door in a position wherein the door leaves an opening in the side wall and the bottom for the passage of poultry, poultry may be loaded to a potion below the opened container segment. In case the container segment is stacked onto another segment in such case the lower container segment may be loaded with live poultry when de door of the higher container segment is opened and the door of the lower container segment is closed.

In an embodiment the side wall section of the door of the container segment may be provided with a least one coupling part that cooperates with the side wall parts of the rest (fixed) of the container segment. For this purpose the side wall parts of the rest (fixed) of the container segment may be provided with at least one counter-coupling segment. The advantages of at least one, or even better two, cooperating coupling and counter coupling parts is that this provides additional strength to the container segment in a position wherein the door is closed. Especially a coupling construction providing a form fitting coupling between the door and the rest of the container segment may result in a substantial increase of the integrity of the container segment in the "closed door situation".

To provide enough passage space if the live poultry the width of the door may be at least <NUM>% of the corresponding width of the side wall wherein the door is installed, but such minimal width may also be at least <NUM>% or at least <NUM>%. Accordingly the depth of the bottom wall section of the door may at least <NUM>% of the corresponding depth of the container segment, but such minimal depth may also be at least <NUM>%, at least <NUM>% or at least <NUM>%. The dimensions are chosen such that the total surface of the bottom section of the door is at least <NUM>% (or at least <NUM>%, at least <NUM>% or even at least <NUM>%) of the total bottom wall surface of the container segment. Such a minimal total surface of the bottom section of the door provides the live poultry enough space to be loaded without hindrance or negative influence on the animal welfare. The height of the door part that forms in the closed situation a section of one of the side walls may have a height in accordance with the height of the sidewall is a part of, however the height may also be <NUM> - <NUM> less than the height of the sidewall is a part of. The advantage of the door part that forms in the closed situation a section of one of the side walls having a reduced height compared to the height of the side wall that it is a part of is that when closing the door poultry (especially poultry heads) are not stuck between the upper edge of the door and a the bottom of a subsequent container segment stacked on top of it. These advantages correspond with the advantages of the locally lowered (longer) sidewall of the container base as may be provided in an embodiment of the container base according the present invention. A further advantage of such a (lowered) door construction is that it enables the opening of a door of a container segment even if there is no space left free above the container segment of which the door has to be opened.

The door may be centrally located in the side wall wherein the door is installed. This provides a balance in the strength of the container segment. Furthermore the height of the door may correspond to the height of the side wall wherein the door is installed, such that in a closed door situation the side walls including the door uniformly surround the poultry holding volume. Also the side walls protruding from the bottom wall may correspond in height so to enable easy stacking of another container segment on top of the container segment. For easy stacking the side walls faces away from the bottom may also be provided with a support edge for carrying an upper part as well as that the bottom side facing away from the side walls may be profiled to hold the top side of the walls from an underlying container segment or a container base according the present invention. For enhanced robustness and user-friendliness the container segment may be provided with rounded off corners.

As for the movability of the door the door is slideable connected with the rest of the bottom wall, while the rest of the bottom wall may be provided with the door holding guides. In case the bottom section of the door has plural segments (e.g. at least two telescopic door bottom segments) the slideable segments may also be constructed such that they overlap in an opened position of the door. The door may also be hingedly connected with the rest of the bottom. As a further preferred alternative the bottom section of the door may have plural segments; one of which rotatable/hinged with another segment and the combined segments being slideable connected to the rest of the bottom wall. Using such construction the segments may in a single smooth movement be "folded" together and subsequently the folded together segments may be shifted backwards. Such construction may not only easy to be handled in opening and losing but also enables to provide a relative large door opening in the bottom wall of the container segment without a voluminous opened door being of hindrance.

To provide the live poultry stored in the container segment air the bottom wall and/or at least one of the side walls may be air permeable. Such air permeability may be realised by providing the walls and/or the bottom with e.g. apertures or a pattern of apertures. The container segment may mainly or completely be constructed of plastic, but also metal construction elements may be incorporated. For instance a metal (e.g. RVS) reinforcement structure may be incorporated in a plastic outer shell. Especially at the border of the aperture in the bottom wall that is provided to receive the door a metal construction (like for instance a metal frame work) may be included as especially this border may be a weaker part of the construction. The metal reinforcement structure may also connect to one or more support structures that may be incorporated in the container segment for carrying the weight of structures stacked on top of the container segment.

Also in an embodiment of the container segment the sidewalls may locally, more especially adjoining the corners of the container segment, be provided with an inward set back wall parts in line with an embodiment of the container base also provided with inward set back wall parts. Also here the inward set back wall parts may gradually sloping inward from the bottom or set back in a non-gradual configuration and - again - the advantage of such feature is that that they enable access to the underside of an element (e.g. a further container segment or a container cover) stacked onto the container base. Such easy access to the underside of an element to facilitate easy stacking and unstacking of a container assembly.

As to provide additional support to elements stacked onto a container element also additional support surfaces me be provided on the upper wall sides of the side walls of the container element.

In a further embodiment of the container segment the bottom wall of the container segment may be provided with a structure of ridges that facilitates the loading and offloading of poultry by including guide structures that lead from a location close to the door to the side walls faced away from the door. The bottom wall may for instance be provided with fanning out ridges (ribs). Furthermore (linear) guide structure of the door may be incorporated in raised bottom wall parts (ridges) to enable (pure) horizontal siding of the door over a certain distance and also providing additional "grip" to the poultry held by the container segment. Yet a further advantage of locally raised bottom wall parts like ridges is that such structure may provide additional strength to the bottom wall. This also helps to lower the price if the bottom wall as it may facilitate the construction of the bottom wall (at least partially) from a plastic material.

The present disclosure also describes a container cover to screen off a container segment. To use the holding volume the top container segment of a stack (pile) of a container base and one or more container segments the top container segment may be closed off with a container cover. Such container cover plate may be a single element plate (e.g. from plastic) but it is also possible to embody the cover plate as a multiple slideable segmented plate with the elements moveable connected with each other. The advantage of a slideable segmented container cover is that it may be opened and closed without the requirement of space above the container cover (as the opening and/of closing takes place more or less in a single plane) which is especially advantageous on the top of a container assembly as there is often few space left, e.g. when a truck is to be loaded with a container assembly it is efficient to use as much of the available transportation volume as possible.

In an embodiment of the container cover the container over is provided with corner apertures that enable to stack and position the container cover relative to an underlying container segment. The apertures in the container cover however prevent further stacking of subsequent container segments or a container base on top of the cover.

The present invention also provides a container assembly for holding live poultry, comprising a container base and at least one container segment, both according the present invention, the at least one container segment being placed on top of the container base. An advantage of such container assembly is that the height/capacity of the assembly may be selected dependent on actual circumstances. For instance dependent on the transport volume the height of the assembly (thus the number of container segments stacked onto a container base) may be optimised. The container assembly may comprise at least two container segments, a first container segment placed on top of the container base and subsequent container segments on top of an underlying container segments. However in practise it is expected that more often container assemblies with four or five container segments will be used. Different from the prior art support structures use in a container assembly in the present container assembly the frame is an integrated part of the container base and the container segments. Due to the use of the container base for holding poultry and the absence of a support structure the poultry holding efficiency may be enhanced with <NUM> - <NUM>% compared to standard prior art live poultry holding solutions.

Finally the present invention also provides a method for loading a container assembly according the present invention, comprising the method steps: A) placing an empty container segment on an empty container base; B) placing one or more subsequent empty container segments on a top empty container segment; C) placing the doors of all the container segments stacked onto the container base in the position wherein the doors leave an opening in the side walls and the bottoms of the stacked empty container segments for the passage of poultry; D) loading live poultry through the opening in the side walls and the bottoms of the stacked container segments into the container base; E) placing the door of the lower container segment in the position wherein it fits the rest of the container segment; F) loading live poultry through the remaining opening in the side walls and the bottoms of the container segments in the lower container segment with the closed door; G) repeating the method steps E) and F) until all the doors of the container segments are closed and the container segments are loaded with live poultry; and H) closing off the upper container segment. The method may furthermore also comprise the method steps: J) loading live poultry in the upper container segment; and K) placing a cover on the loaded upper container segment. The opening and closing of the doors may single-handed be executed enabling a single person to handle the complete loading as one hand is to be used for manipulating the doors while second hand is available to guide the live poultry in the base and segments. The method according the invention enable sound ergonomic single operator loading of live poultry holders which also leads to substantial limitation of loading efforts and thus also loading expenses compared to the prior art loading techniques.

The doors may be opened (according processing step C) before stacking the container segments (according processing step B) but it is also possible to open one or more of the doors of the container segments before stacking them (according processing step B). Closing off the upper segment after being loaded with live poultry may be realised by placing a single lid or a segmented container cover on top of the upper segment but it is also possible to place a partially opened container cover on the upper segment before or during the loading of the upper segment and closing off the partially opened cover after loading the upper segment. The container cover may be provided with apertures to enable stacking a next container base on to a covered container segment without the carrying the weight of the container base lying on top. The apertures may be located such that a weight carrying support structure of a container segment is not covered by the container cover so that the weight carrying support structure is free to directly contact a container base stacked on top of the container segment. The container cover may also be constructed so that it is impossible to place a container cover in between two container segments or in between a container base and a stacked onto that container base container segment; the only option that may be provided by the dedicated shape of the container cover is that a container base is stacked onto a lid.

The invention will be further elucidated herein below on the basis of the non-limitative exemplary embodiments shown in the following figures.

<FIG> shows a container base <NUM> for holding live poultry, having two first side walls <NUM> formed by two parallel sockets <NUM> wherein openings <NUM> are provided for handling the container base <NUM>. The first side walls <NUM> are both connected with two parallel second side walls <NUM>, together forming a substantial rectangular "fencing" that surrounds a poultry holding volume <NUM>. In the second side walls <NUM> apertures <NUM> are provided for aeration/ventilation of the poultry holding volume <NUM>. Furthermore a bottom wall <NUM> is connected to the first and second side walls <NUM>, <NUM>.

<FIG> shows an alternative container base <NUM> which also has side walls <NUM> formed by two parallel sockets <NUM> wherein openings <NUM> are provided. Together with two parallel second side walls <NUM>, <NUM>, a bottom <NUM> and the side walls <NUM> a poultry holding volume <NUM> is surrounded. The side wall <NUM> is locally lowered <NUM> to facilitate easy and animal friendly loading of the container base <NUM>. Furthermore the side walls <NUM> and <NUM> are provided with inward set back wall parts <NUM>. These inward set back wall parts <NUM> are gradually sloping inward from the bottom <NUM> and give easy access to the bottom of an element to be stacked onto the container base <NUM>.

In <FIG> a cross sections of a wall part <NUM> of the container base <NUM> is shown including a dotted represented carrying element <NUM> as may be used for stacking and/or unstacking elements on top of the container segment <NUM>. <FIG> shows an alternative cross section of a wall part <NUM> of the container base which wall part is set back in a non-gradual configuration but that also enables a carrying element <NUM> to be moved underneath a elements on top of the container segment including the wall part <NUM>.

<FIG> shows a container segment <NUM> for holding live poultry, with a bottom wall <NUM> and four side walls <NUM> - <NUM> protruding from the bottom wall <NUM>. A door <NUM> formed by a section of one of the side walls <NUM> and a section of the bottom wall <NUM>. As will be demonstrated in the <FIG> the door <NUM> is dual sectioned and displaceable between a position wherein the door <NUM> fits the rest of the container segment, which is the situation shown in <FIG>, and a position wherein the door leaves an opening in the side wall <NUM> and the bottom wall <NUM> for the passage of poultry. The side walls <NUM> - <NUM> of the container segment <NUM> are provided with apertures <NUM> for aeration/ventilation. Furthermore the container segment <NUM> has support columns <NUM> for carrying the weight of structures that can be stacked onto the container segment <NUM>.

<FIG> shows a container segment <NUM>' wherein the side walls <NUM>, <NUM> are provide with inward set back wall parts <NUM> that are gradually sloping inward from the bottom of the container segment <NUM>' and thus provide access to the bottom of an element to be stacked onto the container element <NUM>' in line with the access provided by the alternative container base <NUM> as shown in <FIG>.

<FIG> shows a top view on a bottom <NUM> of a container segment having a door <NUM> surrounded by a bottom part provided with a structure of ridges <NUM> that facilitates the loading and offloading of poultry so as to "guide" the poultry to or from the door36 during loading or unloading of a container segment. The ridges <NUM> are fanning out ridges (ribs). Furthermore (linear) guide structure of the door <NUM> are incorporated in raised bottom ridges <NUM> that to enable horizontal siding of the door <NUM> and that providing additional "grip" to the poultry supported by the bottom <NUM>.

<FIG> shows a schematic side view of the door <NUM> of the container segment <NUM> as shown in <FIG>. In the positon shown in this figure a wall section <NUM> of the door <NUM> is place in line with a sliding door section <NUM> such that the door <NUM> fits the bottom wall <NUM> and the rest of the side wall <NUM> of the container segment <NUM> (see <FIG>). Also depicted in this figure is a guide <NUM> that holds the sliding door section <NUM>. Now in <FIG> the position of door <NUM> is changed from its initial closed position shown in <FIG> to a semi-opened position by pivoting the wall section <NUM> of the door <NUM> according arrow P<NUM> around a hinge <NUM> to a position wherein the door <NUM> is half opened. In <FIG> position of door <NUM> is further changed from its half opened position (<FIG>) to a fully opened position by shifting the sliding door section <NUM> of the door <NUM> according arrow P<NUM> in the guide <NUM>. The door <NUM> as depicted in <FIG> in in a fully opened position which enables the passage of live poultry (not shown).

<FIG> shows a coupling construction of a side wall section <NUM> of a door of a container segment with a rest part <NUM> of a container segment. The side wall section <NUM> is provided with a coupling knob <NUM> that cooperates with a corresponding opening <NUM> in the side wall part <NUM> of the rest (fixed) of the container segment to provide a form fitting coupling in the "closed door situation".

<FIG> shows a perspective schematic view of a container assembly <NUM> wherein on a container base <NUM> as shown in <FIG> subsequently four container segments <NUM> as shown in <FIG> are stacked. The doors <NUM> of all the container segments <NUM> are in the opened position (see <FIG>) so to enable the loading of the container base <NUM> with live poultry. After the container base <NUM> is loaded the door <NUM> of the lower container segment <NUM> may be closed (to the position as depicted in <FIG>). Now the lower container segment <NUM> may be loaded and this procedure may be repeated until all the container segments <NUM> are loaded.

After or during loading of the top container segment <NUM> a container cover <NUM> as shown in <FIG> may be placed on the top container segment <NUM>. The container cover <NUM> is a multiple slideable segmented plate with the three elements <NUM>, <NUM>, <NUM> linear moveable connected with each other. The container cover <NUM> is also provided with corner apertures <NUM> that enable to stack and position the container cover <NUM> relative to an underlying container segment. The apertures <NUM> prevent further stacking of subsequent container segments or a container base on top of the container cover <NUM>.

<FIG> shows a container segment <NUM> with a bottom wall <NUM> wherein a part of the bottom wall is formed by two bottom wall door segments <NUM>, <NUM>. Four side walls <NUM> - <NUM> protrude from the bottom wall <NUM>; two side walls <NUM>, <NUM> on the short side of the container segment <NUM> and two sidewalls <NUM>, <NUM> on the long side of the container segment <NUM>. All the side walls <NUM> - <NUM> are provided with apertures to enable ventilation of the inner space <NUM> (the poultry holding volume) of the container segment <NUM>. The container segment <NUM> is also provided with eight fittings <NUM> that are constructed to carry the weight of one or more container segments (or container bases) stacked on top of the container segment <NUM>. In the container segment <NUM> a door <NUM> is provided which door <NUM> is formed by a side wall door segment <NUM> of one <NUM> of the longer side walls <NUM>, <NUM> and the two already identified bottom wall door segments <NUM>, <NUM>. The side wall door segment <NUM> is lower than adjoining parts <NUM>, <NUM> of the longer side wall <NUM> that fit to the side wall door segment <NUM>. The door <NUM> is moveable connected with the rest of the container segment <NUM> such that the door <NUM> is displaceable between the position wherein the door <NUM> fits the rest of the container segment <NUM> as is shown in <FIG> and a position wherein the <NUM> door leaves an opening in the side wall <NUM> and the bottom <NUM> for the passage of poultry as is shown in <FIG>.

In <FIG> the door <NUM> of container segment <NUM> is opened providing a poultry loading aperture <NUM> for the passage of poultry to a (not depicted) container segment or container base. This will further subsequently better clarified in relation to <FIG>. The door <NUM> is partially slid to towards the long sidewalls <NUM> and bottom wall door segment <NUM> including side wall door segment <NUM> are pivoted inwardly resulting in the folded position of the door <NUM> as depicted.

<FIG> shows an assembly <NUM> of four container segments <NUM> - <NUM> subsequently stacked on top of a container base <NUM>. The container base <NUM> has two parallel first short side walls <NUM> formed by two parallel sockets <NUM> on the open ends of which bevelled guide surfaces <NUM> help to guide lifting forks into the sockets <NUM>. Also two parallel second long side walls <NUM> are formed by two parallel sockets <NUM> on the open ends of which bevelled guide surfaces <NUM> help to guide lifting forks into. On top of the highest container segment <NUM> a container cover <NUM> is placed that incorporates also a door segment <NUM> to enable loading of the container segment <NUM> while it is partially covered. The fittings <NUM> of upper container segment <NUM> are left free by the container cover <NUM>. <FIG> shows the assembly <NUM> in a closed position, in which closed position it enables the transportation of poultry (not depicted here) loaded in the container base <NUM> and container segments <NUM> - <NUM>.

Claim 1:
Container base (<NUM>, <NUM>, <NUM>) for holding live poultry, comprising:
- two mutual first side walls (<NUM>, <NUM>) formed by two parallel sockets (<NUM>, <NUM>), which sockets (<NUM>, <NUM>) are both provided with at least one open end side (<NUM>);
- two mutual parallel second side walls (<NUM>, <NUM>, <NUM>, <NUM>) connecting on opposite sides to the two parallel sockets (<NUM>, <NUM>); and
- a bottom wall (<NUM>) connected to the sockets (<NUM>, <NUM>) and the side walls (<NUM>, <NUM>, <NUM>, <NUM>, <NUM>, <NUM>), such that the sockets (<NUM>, <NUM>) and the side walls (<NUM>, <NUM>, <NUM>, <NUM>, <NUM>, <NUM>) are protruding from the bottom wall (<NUM>) to surround a poultry holding volume (<NUM>, <NUM>) providing a poultry holding volume for the transportation of live poultry between the sockets (<NUM>, <NUM>) and the side walls (<NUM>, <NUM>, <NUM>, <NUM>).