RU2531265C1 - Package box - Google Patents

Abstract

FIELD: packaging industry.

SUBSTANCE: package box comprises a bottom (102), the end walls, and the side walls (108). One of the end and side walls comprises a plurality of inlets (200a-200c) for inflow of the coolant into the box. Each side wall (108a, 108b) comprises the first and second lateral edges located near the respective end walls, the lower edge (124) located adjacent the bottom (102) and the upper edge located at a distance from the bottom (102). One of the end and side walls comprises a plurality of ventilation holes (110). The inlets (200a-200c) have the size greater than that of the ventilation holes. The side wall (108a, 108b) additionally comprises a continuous reinforcement element extending parallel to the first and second lateral edges and parallel to the upper edge. The first inlet (200a) of the plurality of inlets is made on the left part of the side wall (108a, 108b) at a distance from the lower edge (124) with a part of the continuous reinforcement element (116) between the first inlet (200a) and the first lateral edge and upper edge. The second inlet of the plurality of inlets is formed on the right part of the side wall (108a) at a distance from the lower edge (124) with part of the continuous reinforcement element between the second inlet and the second lateral edge and the upper edge.

EFFECT: cooling the content with the liquid in the inner part of the box.

9 cl, 26 dwg

Description

BACKGROUND OF THE INVENTION

Embodiments of the invention relate to a crate or container for storing products, more specifically, embodiments of the invention relate to a plastic crate that is provided for storing and / or transporting food products such as fruits, vegetables, meat and the like.

Boxes for storing and transporting products such as fruits and vegetables are widely used in trade. Such crates are light and durable, which makes them suitable for delivering crops from the field to the customer. For example, for tropical fruits like bananas, it is common practice to harvest when it is still unripe and pack it in crates for shipping and shipping. During this transport, the fruit has time to mature. Also, other fruits, such as apples or the like, or vegetables, like lettuce or the like, as well as meat or eggs can be packed in tare boxes in the manufacturing premises of the producers and transported using such tare boxes.

Before transportation, filled crates are usually placed one on top of the other and placed side by side on two pallets, and the pallets, as a whole, are then transported to the appropriate vehicles. Often, a special technology of cross-mounting to each other is used, for example, “configuration 5 below. In such a configuration 5 below, five container boxes are arranged next to each other in a rectangular array so that two of them form a row in the length direction, and the other three form a row in the width direction. One problem with this type of arrangement is that when the crates are stacked on top of one another in this way, the three crates forming a row in the width direction fit their shorter end walls to the longer side walls of the two crates forming a row in the length direction . Thus, the force acting on the lateral side walls of the arrangement of crate boxes in the length direction is high, especially in the central region of the side walls of crate boxes located in the length direction. This may result in damage to the crates during transport or during installation on top of each other.

The crates described above may be plastic crates that contain opposite end walls and opposite side walls extending from the bottom, which is generally rectangular in shape. Container boxes can also be made of other materials, such as wood, cardboard or the like. The crates can be so-called folding crates, which means that the end walls and side walls can be folded down in the direction of the bottom. This makes it possible to transport empty crates in their folded state, for example to fields where the crop is harvested and directly packed in the corresponding crates. This makes it possible to deliver a large number of folded crates using the minimum vehicle capacity, thereby delivering the folded crates to the desired locations in an economical manner. There are crates of different heights, i.e. some crates have walls extending from the bottom a first distance, while others extend up a second distance, which may be greater than the first distance. The height of the crates, when unfolded, depends on the products to be placed in them and transported. The design of the crate having folding walls may be such that the side walls, when folding down to the bottom, may overlap. In this case, to obtain the minimum possible height, traditional crate boxes require a special sequence of folding the corresponding wall sections. For example, first of all, two end wall sections are to be folded to the bottom, and then the first of the two side walls is folded down so as to be placed on the end walls folded down, and then the second of the side walls is subsequently folded down. The corresponding side walls are made in such a way that the minimum height of the folded crate is obtained without passing any parts beyond this height.

However, this approach is not preferred since it requires the user of the crate to be aware of how to fold the crate, i.e. the corresponding wall sections must be folded in the right way, otherwise the minimum height will not work, and, in addition, the elements of the wall sections can extend beyond the minimum height, thereby eliminating the correct installation of stacked crates on top of each other. One solution to this problem is to provide a protrusion at the edge of the bottom extending upward from the bottom at a predetermined distance, thereby ensuring that no matter how the two side walls are folded, even in the “worst case”, none of the parts of the side walls passes above the upper end of the protrusion. Although this solves the problem of parts extending beyond the height of the folded crate, it increases, at the same time, the height of the folded crate and thereby limits the total number of folded crates that can be stacked and delivered. Although this may seem like a minor problem, when considering only one crate, it is necessary to consider a situation in which a large number of such crates are folded and delivered by being placed on appropriate pallets, and a protrusion having an increased height, as mentioned above, can lead to loss of vehicle capacity by about 15%.

The crates described above, which are collapsible, further comprise a locking mechanism that provides a reliable connection of the side walls and end walls in the unfolded state of the crate. At the same time, an easy-to-handle mechanism should be provided to unlock the latch when it is necessary to fold the crate after all products have been removed and the crate must be delivered back to the supplier, for example for cleaning. Container boxes having collapsible walls therefore comprise unlocking mechanisms that act on the latching elements provided to unlock the latch, thereby allowing downward folding of the corresponding side walls. For example, the side walls may contain corresponding accommodating parts formed on their lateral edge, with the lateral edge being adjacent to the end walls. In the end walls, movable latch mechanisms can be provided, for example, a hook that slides down and engages with the accommodating part in the side wall when the corresponding walls are brought into their vertical position. For example, when moving the side wall from a lower position to a vertical position, the hook rises when passing the side wall elements, and then, due to the downward bias, the hook is placed in the accommodating part. To unlock the latch by the unlocking mechanism, the hook rises, so that the latching elements are released and the side wall can be folded down towards the bottom again.

These mechanisms provide an easy-to-use method for unfolding the crate, however, the mechanisms are generally provided so that they can be activated at any time when the crate is unfolded. This is not preferred since it also provides the ability to activate the unlocking mechanism when a plurality of crate boxes are mounted on top of each other, for example on a pallet. In such a situation, due to impact or improper handling, the latch mechanism of one or more of the crates inside the stack can be activated, thereby unlocking the corresponding wall element, making the stack generally unstable. In the worst case scenario, this can lead to collapse of the stack, since one or more of the crates inside the stack can no longer provide the required stability to support crates mounted one on top of the other.

As mentioned above, crate boxes can be used to transport food products like vegetables, fruits and meat or the like. These products may require refrigeration and, therefore, it is required to provide coolant like ice water or the like inside the crate, ensuring that the goods remain fresh and / or at the required temperature. Although tare boxes typically have openings in the side walls and bottom to allow air to circulate, these openings may not be sufficient to provide sufficient coolant flow inside the tare box, for example, when using ice water, it is likely that ice particles are in the stream fluids that cannot enter the openings provided for air ventilation, and which can actually block the openings, thereby eliminating the fact that the liquid reaches the inside of the crate.

SUMMARY OF THE INVENTION

Embodiments of the invention provide improved crates that overcome one or more of the problems of traditional crates described above.

According to a first aspect, embodiments of the invention provide a crate including a bottom, two end walls and two side walls. Each of the side walls includes a first lateral edge located next to the first end wall, a second lateral edge located next to the second end wall, a lower edge located near the bottom, and an upper edge located at a distance from the bottom. Each side wall includes a continuous stiffener extending parallel to the lateral edges and at least partially to the upper edge. The continuous stiffening element includes a stiffening portion extending in at least one region between the lateral edges from the upper edge towards the lower edge and back to the upper edge.

In accordance with embodiments, the stiffening portion is U-shaped and extends in the central region of the side wall toward the lower edge. In embodiments of the invention, the stiffening portion extends toward the lower edge such that the distance to the lower edge is less than or equal to half the height of the side wall. Alternatively, the stiffener may extend to the lower edge of the side wall.

Embodiments may include a continuous stiffener having a plurality of stiffeners extending toward the lower edge of the side wall. In such embodiments, the plurality of stiffeners may have the same or different distances to the lower edge of the side wall.

Embodiments of the invention may provide a crate that is made of plastic, and a continuous stiffener may be formed by injection molding with water. The crate can be collapsible, so the end walls and side walls can be folded relative to the bottom.

Embodiments of the invention in accordance with the second aspect provide a crate comprising a bottom having two protrusions located on opposite sides of the length and extending upward from the bottom, two opposite end walls extending along the sides of the width of the bottom, and two opposite side walls extending along the sides of the bottom. The end walls and side walls are designed so as to be folding relative to the bottom. The side walls have a height such that the side walls are at least partially overlapped when folding. Each side wall is connected to the bottom by at least one hinge, and each hinge is slidably mounted in the protrusion so that the hinge is movable between the lower end of the protrusion located near the bottom and the upper end of the protrusion.

According to embodiments, the height of the protrusion above the bottom corresponds essentially to the thickness of the two side walls. According to embodiments, in the unfolded state, the lower ends of the side walls are placed on the upper surface of the corresponding protrusions with hinges for both side walls in the lower position, near the bottom, and when folded, the lower ends of the side walls are opposite relative to the inner surfaces of the corresponding protrusions with hinges of the side walls at different heights in the protrusion, with one side wall being placed on the end walls folded to the bottom, and the other side wall, at least re, partially, is placed on one side wall.

In accordance with embodiments, the hinge of one side wall located on the end walls remains in the lower position, and the hinge of the other side wall is in the position above the lower position, thereby making it possible to arrange the folded side walls so as to substantially be parallel to the bottom, with the outer surface of the other side wall essentially being at the same level as the upper surface of the protrusions.

In accordance with embodiments, the hinges may be configured such that when folded there is a gap between the lower surface of the side walls and the corresponding inner surfaces of the protrusions. The hinge may include an elongated rod connecting the hinge element in the protrusion and the side wall. The elongated rod defines the gap and has a length specified by the distance between the lower portion of the hinge and the height of the protrusion. Each side wall may include multiple hinges.

Embodiments of the invention in accordance with a third aspect provide a crate comprising a bottom, two end walls and two side walls. The end walls and side walls are designed so as to be folding relative to the bottom. The end walls and side walls comprise corresponding snap elements engaged with each other to form a latch when the end walls and side walls are in an unfolded state. A latch release mechanism is provided on the respective end walls or on the respective side walls, the latch release mechanism and / or the latching elements on the respective walls are configured to be movable so as to extend above the upper edge of the corresponding wall to release the latch.

Embodiments provide a latch release mechanism that includes a lifting beam having opposite ends connected to latching elements of one of the walls and shaped so that at least a portion of the latch release mechanism extends above the upper edge of the wall when in unlocked position.

According to other embodiments, one of the engaging snap elements is movable and the other is stationary, wherein the movable snap element is configured to extend above the upper edge of the wall when it is in the unlocking position of the fixed edge element. The movable latching element, when in the unlocked position, can be designed to fold with a wall moving toward the bottom.

According to a fourth aspect, embodiments of the invention provide a crate including a bottom, two end walls and two side walls. At least one of the end and side walls contains an inlet having a size that enables the introduction of a predetermined amount of coolant inside the crate.

In accordance with embodiments, at least two opposing walls may comprise a plurality of inlets, for example, each side wall may comprise a plurality of inlets. In accordance with embodiments, each side wall includes first and second lateral edges located adjacent to respective end walls, a lower edge located near the bottom, and an upper edge located at a distance from the bottom. The first inlet is located near the first upper corner of the side wall near the first lateral edge and the upper edge, and the second inlet is located near the second upper corner of the side wall near the second lateral edge and the upper edge.

Other embodiments provide side walls having a continuous stiffener extending parallel to the first and second lateral edges and parallel to the upper edge, with the U-shaped portion in the central region extending toward the lower edge. The first inlet is provided on the left side wall portion at a distance from the lower edge with a portion of the continuous stiffener between the second inlet and the first lateral edge, the upper edge and the central region. A second inlet is provided on a right side wall portion at a distance from the lower edge with a portion of the continuous stiffener between the second inlet and the second lateral edge, the upper edge and the central region.

According to embodiments, a third inlet can be provided in the central region of the side wall at a distance from the upper edge and with a portion of the continuous stiffening element between the third inlet and the lower edge, the left portion and the right portion. The third inlet may have a size that is smaller than the size of the first and second inlet. The inlets can be provided with a grid (grid) having a mesh size, allowing the passage of liquid, for example, ice water having ice particles in it.

Embodiments of the invention in accordance with the first to fourth aspect may provide crates that are made of plastic and which are intended to house and / or transport food products like fruits, vegetables, meat and the like.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments of the invention will be described with reference to the accompanying drawings, in which:

Figure 1 is a perspective view of a crate;

Figure 2 is a side view of the crate of Figure 1;

Figure 3 is a schematic representation of one layer of a crate stack stack provided in a configuration 5 below;

Figure 4 shows an embodiment of a side wall of a crate having a modified stiffener;

Figure 5 (a) to (c) shows different configurations of the modified stiffener element of Figure 4;

6 is a cross section of a crate, taken in the central position of the crate shown in FIG. 1;

In Fig.7 shows the correct (Fig.7 (a)) and incorrect (Fig.7 (b)) folding the crate shown in Fig.6;

Fig. 8 is a cross-sectional view similar to Fig. 6, showing a modified hinge structure in accordance with embodiments of the invention;

Fig. 9 shows the situation when the crate of Fig. 8 is folded down either with the side wall 108b folded first (Fig. 9 (a)) or with the side wall 108a folded first (Fig. 9 (b));

Figure 10 shows an example of a traditional latch mechanism, with Figure 10 (a) showing the first side wall of the crate, and Figure 10 (b) showing an example of a latch mechanism in an enlarged view;

FIG. 11 shows an additional example of a conventional latch mechanism, wherein FIG. 11 (a) shows a similar arrangement as in FIG. 10 (a) and FIG. 11 (b) shows an enlarged view of the latch mechanism in accordance with this example ;

12 shows a locking mechanism in accordance with an embodiment of the invention;

Fig. 13 shows a crate of Fig. 12 with a lifting beam in an unlocked position;

Fig. 14 shows an example of two crates mounted on top of each other;

FIG. 15 is a side view of a crate in accordance with embodiments of a fourth aspect of the invention; and

Fig. 16 shows a similar construction as in Fig. 15, except that the side wall has a construction as shown in Fig. 4.

DESCRIPTION OF EMBODIMENTS OF THE INVENTION

In the following description, various aspects of the crate will be described, namely, the aspect of providing an additional central stiffener to prevent damage to the side walls of the crate, the aspect of providing movable hinges of the folding side walls, allowing folding of the side walls of the crate, which are folded in an arbitrary state when folded, an aspect of providing a latch mechanism / latch release mechanism to prevent accidentally opening a latch of installed drills g to other crates, and provide inlet side for inputting the coolant, similar to ice water, into the interior of the crate. However, first of all, crate elements that are common to all aspects will be described with respect to FIG. 1 below.

FIG. 1 is a perspective view of a crate 100 containing a bottom 102, which may comprise a plurality of openings 104. The crate 100 further comprises a first end wall 106a and a second end wall 106b that is opposed to the first end wall 106a. Moreover, two opposite side walls 108a and 108b are provided oppositely with respect to each other. As can be seen, the side walls 108a and 108b are longer than the end walls 106a and 106b. In accordance with embodiments of the invention, the side walls and end walls can be folded toward the bottom 102, such that, for example, the end walls 106a and 106b first fold to the bottom, and then the side walls 108a and 108b fold toward the bottom. The size of the side walls in the height direction can be such that when they are folded towards the bottom, the side walls can overlap. The advantage of folding the side walls and end walls towards the bottom is that the residual volume of the crate is minimal, so when folded the crate is only small in height, so a large number of empty crates can be stacked on top of each other, for example, on one pallet for transportation. According to embodiments of the invention, the crate is made of plastic, thereby providing low weight and high stability for storage and / or transport applications. In addition to the holes 104 in the bottom 102, also the holes 110 are formed in the respective walls and can provide ventilation holes. Moreover, large openings 112a and 112b are provided in the upper part of the end walls 106a and 106b, while the openings 112a and 112b define the gripping holes. As can be seen, the upper edge 114a and 114b of the end walls can have an increased thickness, thereby ensuring that the transfer of the crate while gripping the gripping holes 112a and 112b is reliable and that sufficient strength of the end wall portion above the gripping holes is ensured.

The first aspect is the "central section of rigidity"

Embodiments of the invention in accordance with the first aspect will now be described. FIG. 2 shows a side view of the crate 100. FIG. 2 (a) shows a first side face 108a that extends upward from the bottom 102. As mentioned above, when the crate is a collapsible crate, FIG. 2 (a) shows a side wall 108a in its upright or unfolded position. Moreover, a plurality of ventilation holes 110 are shown. The side wall 108a comprises a stiffener 116 having a first portion extending parallel to the first lateral edge 118 of the side wall 108a. The lateral edge 118, for example, is located adjacent to the first end face 106a shown in FIG. The stiffener 116 also extends parallel to the second lateral edge 120 of the side wall 108a, with the second lateral edge 120 located adjacent to the second end wall 106b. The stiffening element, moreover, runs parallel to the upper edge 122 of the side wall 108a, with the upper edge 122 being at a distance from the lower edge 124, which, in turn, is adjacent to the bottom 102. As shown in FIG. 2 (a), the stiffening element 116 is a continuous stiffening element, which, for example, was obtained during the molding of the plastic side wall 108a using an injection molding process with water injection. The continuous stiffening element 106 extends, as mentioned above, parallel and adjacent to the first lateral edge, the upper edge and the second lateral edge as shown in FIG. 1, and ventilation holes 110 are provided in a region of the side wall 108a that is surrounded by the stiffening element 116 and bottom edge 124.

Figure 2 (b) shows a cross section of the side wall 108a along the line b-b '. As can be seen, the stiffener 116 has a hollow structure with a cavity 116a therein, which is formed by injection molding with water and provides an element having high stiffness with a reduced amount of material and thereby also with a reduced weight.

The side wall structure shown in FIG. 2 (a) is not preferred in situations where a plurality of crate boxes are mounted on top of each other in the aforementioned configuration 5 below. Figure 3 is a schematic representation of one layer of a stack of crate boxes provided in configuration 5 below. As you can see, the three crates 100a-100c are located side by side, i.e. the side walls of the crates 100a-100c are adjacent. In addition, two additional crate boxes 100d and 100e are located adjacent to the end walls of the crate boxes 100a-100c so that the two end walls of the crate boxes 100d and 100e are adjacent. Thus, as can be seen from FIG. 3, the shorter end walls of the crate boxes 100a-100c are adjacent to the longer side walls of the crate boxes 100d and 100e, leading to the aforementioned problem that the force acting on the side walls of the crate crates 100d and 100e are large in the central part of the side wall and can lead to damage to crates 100d and 100e if one or more of the crates 100a-100c is moved during an impact or the like. For example, when installed on top of each other, tare boxes 100e and 100d are first provided, and then additional tare boxes 100a-100c are added, and during the placement of additional tare boxes 100a-100c, they can hit the side walls of the tare boxes 100d and 100e, leading to possible damage to the side walls.

Thus, the stiffness design of the side wall of the crate shown in FIG. 2 (a), which works well when the crates are parallel to each other, like the crates 100a-100c, is not preferred when the crates are arranged as shown Figure 3.

Thus, in accordance with embodiments of the invention related to the first aspect, a modified stiffener is provided. Figure 4 shows an embodiment of such a modified stiffener. 4 shows a side wall 108a having a modified stiffener 126. In addition, the stiffening element 126 has a first part 126a extending parallel to and adjacent to the first lateral edge 118. The second part 126b of the modified stiffening element 126 extends parallel and adjacent to the second lateral edge. The modified stiffener 126 is also a continuous stiffener extending continuously from the lower left corner of the side wall 108a along the lateral edge 118 and along the upper edge towards the second lateral edge and down to the lower right corner of the side wall 108a. The modified stiffener 126 further comprises a U-shaped portion 128 in the central region of the side wall 108a. The U-shaped 128 contains two vertical stiffener parts 126c and 126d that are substantially parallel to the 126a and 126b. Moreover, a portion 126e is provided adjacent to the lower edge 124. In the left and right areas outside the central portion of the side wall 108a, the modified stiffener 126 comprises portions 126f and 126g located adjacent to the upper edge 122. As mentioned above, the modified stiffener 126 represents is a continuous element, i.e. all parts 126a-136e are connected to each other, thereby forming a continuous element in the manner as shown in FIG. 4. Vent holes 110 are provided on the left and right portions of the side wall, with a stiffening element provided between the vents and lateral edges 118 and 120, respectively, of the center region and the upper edge 122. In the center region, vents are provided with a stiffener between the left and right portions and bottom edge 124.

The design of FIG. 4 provides increased rigidity of the side wall 108a and the central portion, thereby eliminating damage in situations as described above when a plurality of crate boxes are mounted on top of each other in the configuration 5 below shown in FIG. 3.

Embodiments of the first aspect are not limited to the configuration shown in FIG. 4; on the contrary, different configurations of the modified stiffener 126 can be provided. Such embodiments are now described with respect to FIGS. 5 (a) to (c). In the respective figures, a side wall 108a, also described with respect to FIG. 4, with correspondingly modified stiffening elements 126 is schematically shown. In the embodiment shown in FIG. 5 (a), the side wall comprises two U-shaped portions of the modified stiffener, both of which extend completely toward the lower edge. FIG. 5 (b) shows a schematic representation of another embodiment in which a U-shaped portion of a stiffening element extends only half the height of the side wall 108a down towards the lower edge. Fig. 5 (c) shows a schematic representation of yet another embodiment using three U-shaped sections of the stiffener with different "depths", i.e. passing by different sizes towards the lower edge of the side wall.

Although the embodiments described above refer to U-shaped sections of the stiffener extending toward the lower edge, it should be noted that the invention is not limited to such embodiments. Conversely, in accordance with further embodiments, the portion of the stiffener extending in the region of the side wall from the lateral edges toward the bottom may be different, for example, the portion may be V-shaped or may also have an asymmetric shape, if required.

The second aspect is the "movable joints"

Embodiments of the invention in accordance with a second aspect will be described hereinafter. The second aspect relates to folding the side walls of the crate, which, when folded down to the bottom, overlap each other. As mentioned above, the folding down order of the side walls in accordance with traditional crate boxes requires compliance so that the crate is correctly folded to obtain a minimum residual volume of the folded crate.

Figure 6 shows a cross section of a crate, and this cross section is taken in the Central position of the crate, shown, for example, in Figure 1. The crate 100 shown in FIG. 6 comprises a bottom 102 and side walls 108a and 108b. The bottom 102 comprises protrusions 102a and 102b that extend upward from the bottom 102. The protrusions 102a and 102b are located on the outer edges of the bottom 102 and may be integral with the bottom 102. The first protrusion 102a comprises a first hinge 150a, which is shown schematically in FIG. .6. The first hinge 150a provides a connection between the protrusion 102a and the first side wall 108a so that the side wall can rotate in the direction indicated by arrow 152a. As is known from traditional crate boxes, means may be provided to ensure that the side wall 108a is moved only from a downward position on the bottom 102 to a vertical position, as shown in FIG. 6, so that the bottom surface 154a on the side wall 100a is located near or on the upper surface of the protrusion 102a. Similarly, a second hinge 150b is provided in the second protrusion 102b, however, as can be seen from FIG. 4, the hinges 150a and 150b are located at different heights relative to the bottom 102. The hinge 150b is connected by means of a connecting rod 156 to the side wall 100b so that it can rotate in the direction of arrow 152b toward the bottom 102.

According to a container having a structure as shown in FIG. 6, it is required that the side walls 108a and 108b fold down in the correct order to ensure a minimum volume of the folded container. In Fig.7 shows the correct and incorrect folding of the crate shown in Fig.6. In accordance with the crate shown in FIG. 6, in order to correctly fold, first of all, it is required to fold down the side wall 108b so that it is placed next to the bottom 102. Then, the second wall 108a is folded down. Subject to this correct order, the outer surface of the side wall 108a will be substantially at the same height from the bottom 102 as the upper surfaces 158a and 158b of the protrusions 102a and 102b. The side walls 108a and 108b are arranged so that their lower surfaces 154a and 154b are adjacent to the inner side walls of the protrusions 102a and 102b. As can be seen from Fig. 7 (a), observing the correct folding order results in a folded crate having a minimum volume.

However, when the folding order described with respect to FIG. 7 (a) is not respected, a result is obtained as shown in FIG. 7 (b). As you can see, when the side wall 108 (a) is folded down first, it is only located on its front or top near the bottom 102, while the second surface 108b is placed on the first surface 108a in such a way that at least partially the outer wall of the second side wall 108b is above the level of the upper surfaces 158a and 158b of the protrusions 102a and 102b.

Thus, it is not possible to stack a folded crate on top of one another, as the entire stack will become unstable. Therefore, a conventional solution to this problem is to provide the protrusions 102a and 102b with such a height that regardless of the folding order of the side walls 108a and 108b, the upper level of the downwardly folded side walls corresponds essentially to the height of the upper surfaces of the protrusions 102a and 102b. Despite the fact that this solves the problem of possible unstable stacks of folded crates, at the same time, it reduces the number of folded crates that can be stacked on top of each other, as the minimum volume of folded down crates is increased.

In accordance with the studies of the inventors of the invention, it was found that the increase in the minimum volume can be such that the total number of containers that can be transported on a common pallet can be reduced up to 15%, leading to increased transportation costs, which is undesirable.

Therefore, in accordance with embodiments of the invention, the hinge structure of the crate is modified in a manner as described in more detail below. On Fig shows a cross section similar to Fig.6, however, showing a modified hinge structure. The bottom 102 and the protrusions 102a and 102b, as well as the side walls 108a and 108b are again shown. Hinges 150a and 150b are provided in the protrusions 102a and 102b, however, each hinge is movably located in the recess in the protrusion 102a and 102b and is connected via respective rods 160a, 160b to the respective side walls 108a and 108b. In the position shown in FIG. 8, the side walls are folded up and upright so that their lower surfaces are adjacent to the upper surfaces of the protrusions. The position of the hinge 150b is essentially the same as the position of the hinge in FIG. 6, however, the position of the hinge 150a is at the same level as the hinge 150b, while in FIG. 6 the two hinges were at different levels.

When folding the crate, as shown in FIG. 8, it does not matter whether the side wall 108a and then the side wall 108b fold down first, or vice versa. Fig. 9 shows a situation where the crate of Fig. 8 is folded down either with a side wall 108b folded first or with a side wall 108a folded first. In FIG. 9 (a), it can be seen that the second side wall 108b was folded first, so that it is adjacent to the bottom 102. In this situation, the hinge 150b remains essentially in the position as shown in FIG. 8, and the gap between the lower surface of the side wall 108b and the inner side wall of the protrusion 102b is determined by the length of the rod 160b. On the other hand, the hinge 150a is moved from the position shown in FIG. 8 to the upper position, allowing the first side wall 108a to be placed on the second side wall 108b so that the level of the outer surface of the side wall 108a corresponds essentially to the upper surface of the protrusions 102a and 102b.

Fig. 9 (b) shows a similar arrangement, however, with the first side wall 108a folded down first so that the hinge 150a remains in the position as in Fig. 8. As explained with respect to FIG. 7 (a) in this case, the hinge 150b of the second side wall 108b has the ability to move upward, so that in this case the outer surface of the side wall 108b is at a level corresponding essentially to the upper surface of the protrusion 102a and 102b. By providing the respective hinges so that they are movable, the situation, as shown in FIG. 7 (b), is eliminated, as can be seen from FIG. 9 (b). Thus, in accordance with embodiments of the invention, it is not necessary to increase the height of the protrusions, on the contrary, by design in accordance with embodiments of the invention, the upper level of the downwardly folded side walls is always substantially the same as the upper surface of the protrusions 102a and 102b, independently whether the first side wall 108a or the second side wall 108b is folded down first. By eliminating the increase in the height of the protrusions, the total number of folded crates that can be transported on the pallet at the same time can be increased, so transporting the crates folded down is more efficient than with traditional approaches.

6-9, a cross section of a crate was shown without end walls. However, it should be noted that it is also necessary to fold the end walls to obtain a folded down crate and, in accordance with embodiments, the end walls are folded down first, so that the side walls, after folding down, are located near the bottom, but are located at least , partially on the folded down end walls. Other embodiments may take place whereby the end walls fold down only when the side walls have been folded down, in which case the principles of the embodiments described with respect to the second aspect also apply.

The third aspect is the “latch / release mechanism of the latch”

Embodiments of the invention in accordance with a third aspect will be described hereinafter. Conventional folding crates have corresponding latch mechanisms that provide a latching operation that holds the end walls and side walls together in their upright position. An example of such a latch mechanism is to provide a pair of movable latches in the end walls of a folding crate that are vertically engaged with corresponding elements to accommodate latches that are provided in adjacent side walls. Naturally, corresponding latches and elements for accommodating latches can be provided on the contrary, i.e. latches can be provided in the side walls, and elements for accommodating latches can be provided in the end walls.

10 shows a first example of a conventional latch mechanism. 10 (a), the crate 100 shows a first side wall 106a having a plurality of ventilation openings 110. By hinges 170a and 170b of the end wall, the end wall 106a is rotatably mounted relative to the bottom 102, allowing the end wall 106a to rotate towards bottom when folding down. Moreover, side walls 108a and 108b are shown. In the region above the gripping hole 112a, the upper part 172 of the side wall 106a is shown reinforced, so that when carrying the crate, sufficient rigidity and strength are ensured, and breaking of the upper part above the gripping hole 112a is excluded. Moreover, two latch mechanisms 174a and 174b are provided in the end wall. 10 (b) shows an example of an enlarged latch mechanism 174a. In this example, the latch 176 is mounted in a recess 178 in the end wall 106a. The latch 176 is biased outwardly by a spring member 180 also provided in the recess 178. In the side wall 108a, the recess 182 is provided to receive the latch 176 so that a latch between the side wall and the end wall is achieved. To unlock the latch mechanism, a suitable actuator is provided in the latch mechanism 174a, which allows the latch 176 to move inward, i.e. away from the side wall 108a, thereby disengaging the latch 176 with the latch accommodating or the mating element 184 provided in the recess 182. Once the latch has been unlocked, the end wall can fold down to the bottom and, consequently, the side wall can also fold way down.

11 shows a further example of a conventional latch mechanism. Fig. 11 (a) shows a similar construction as shown in Fig. 10 (a), except that the latch mechanism is different. The latch mechanism comprises a lifting beam 186, which can be moved vertically, as shown by arrow 188. FIG. 11 (b) shows an enlarged view of a latch mechanism in accordance with this example. As can be seen, the outer ends of the lifting beam 186 are provided with a hook 190 or a latch which is located in the recess 182 of the side wall 108 (a) and engages with the latching mating element 184. The lifting beam 186 is biased towards the bottom, so that when the side the walls and end walls are in a vertical position, the hook is forced to move into the element 184, thereby reliably snapping the side walls and end walls. To unlock the side walls and end walls, the lifting beam rises up, thereby disengaging the hook from the element 184 and allowing the end wall 106a to be moved or rotated down to the bottom.

Despite the fact that the latching mechanisms generally work well and provide reliable fastening of the corresponding wall sections when they are upright, there is a drawback in that the latching mechanisms can also be unlocked in cases where a plurality of crate boxes are mounted on top each other. This can lead to the above problems. For example, due to impact or improper handling of the crate when mounted on top of each other on a pallet, the latching mechanism of one or more of these crates can be unlocked, for example, by impact, which causes the latching elements to move in their unlocking direction. This can lead to a situation in which one or more of the crates in the crate stack has unclosed walls, so the structural integrity of the entire stack is compromised, as one or more of the crates can fall apart, so additional crates mounted on top of it will also fall.

To avoid such situations, embodiments of the invention in accordance with a third aspect provide a new latch mechanism, as will be described below with respect to FIG. 12 shows a locking mechanism in accordance with an embodiment of the invention. The mechanism shown in FIG. 12 is similar to the mechanism shown in FIG. 11 (a), except that the lifting beam 186 is provided in such a way that at least one part 186a and 186b must be unlocked to unlock the latch or lock move so as to pass over the height of the crate or over the top edge of the crate. In this case, the latch mechanism, as shown in FIG. 12, may be similar to the latch mechanism shown in FIG. 11 (b), except that it is provided near the upper edge of the end wall 106a and the side wall 108a. 12 (a) shows a crate with a lifting beam 186 in the unlocked position, and, as can be seen, parts 186a and 186b extend above the top edge of the crate at a distance d. This provides the ability to easily lock / unlock tare boxes. However, it is necessary to move the latch mechanism above the height of the crate to unlock. This eliminates the problem of installing multiple container boxes on top of each other.

13 is a side view of a crate having a new latch mechanism in accordance with another embodiment of the invention. FIG. 13 (a) shows a crate with a latch mechanism that locks the side wall relative to the end wall, while FIG. 13 (b) shows the latch mechanism in the unlocked position. More specifically, in accordance with the embodiment of FIG. 13, similar to other embodiments, the crate comprises a bottom 102 and an end wall 106a. It should be noted that the opposite end wall 106b has the same structure as that shown in FIG. 13 (a). Moreover, two side walls 108a and 108b are shown. In the corner portions of the crate, each side wall 108a and 108b comprises a protrusion 190a and 190b having a thickness corresponding to the thickness of the end wall 106a. The protrusions 190a and 190b may comprise a plurality of slots 192 which are provided with accommodating protrusions provided on the front face of the side wall 106a to increase the stability of the connection between the side wall and the end wall. The lifting mechanism 186 is constituted by an arcuate element having end portions 186a and 186b that are flush with the top edge of the crate in the latched position. The lifting mechanism 186 comprises two pins 194a and 194b that extend into the crate through recesses 196a and 196b extending in the vertical direction and provided in the end wall 106a. By means of pins and recesses 194 and 196, a predetermined movement of the lifting mechanism 186 in the vertical direction is provided, while undesirable movement in the transverse direction is excluded. In addition, the lifting mechanism comprises spring elements 198a and 198b having one end connected to the mechanism 106 and the other end adjacent to the lower surface of the upper beam 199 of the front wall or side wall 106a. The spring elements 198 are supported abut against the beam 199 and do not need to be attached to it, however, in embodiments the connection with the beam 199 can also be ensured. The elements 198 are made of the same material as the lifting beam and the crate, for example, plastic material. Alternative embodiments may also use other spring elements made of another material, like a metal or the like. Elements 198 bias the lifting beam 196 to a position as shown in FIG. 13 (a).

13 (b) shows the lifting mechanism 186 in its unlocked position. As can be seen, the lifting beam 108 is moved against the biasing force of the spring elements 190a and 190b to a position that is closer to the beam 199 than in the locked position shown in FIG. 13 (a). Moving the mechanism 186 in this direction leads to elastic deformation of the elements 198 in such a way that, when the lifting mechanism 186 is unlocked, it is prompted to move back to the position shown in FIG. 13 (a). As can be seen from FIG. 13 (b), raising the element 186 causes the end portions 186a and 186b to be lifted, so that the elements 186a and 186b are released from the corresponding locking pins 187a and 187b located on the upper surface of the protrusions 192a and 192b that engage with a corresponding opening or recess in the elements 186a and 186b for locking the end wall and side walls with each other.

In the position as shown in FIG. 13 (b), the locking mechanism is unlocked, thereby allowing folding of the end wall down to the bottom, and then the side walls can be folded down to the bottom.

As can be seen from FIG. 13 (b), as in the embodiment described with respect to FIG. 12, also here, the elements 186a and 186b are moved above the top edge of the crate so that the mechanism 186 cannot be activated and is secured to the position shown in FIG. 13 (b) when one or more other crates are mounted on top of each other over the crate shown in FIG. 13 (b).

Another advantage of the solution described with respect to the embodiments of the invention with respect to the locking mechanism is that it is not necessary to provide expensive material for forming the elastic elements 198a and 198b, on the contrary, in accordance with embodiments, the same material from which the crate is made in general, for example, the same plastic material. Traditional approaches suffer from the disadvantage that the same material is used to form a crate and elastic elements, such as a plastic material. During the life of the container, the spring element (the material from which it is made) may lose all or part of its elastic characteristics. In such a situation, the force to maintain / bias the lifting mechanism to the position shown in FIG. 13 (a) is lost or reduced. The risk of unlocking is increased, even if a small amount of force is applied to the crate. In accordance with embodiments of the invention, such problems are eliminated, since in the case of securing the crate to the stack with other crates from above (which is common when transporting filled crates), the lifting beam is maintained in the locked position not only by the biasing force directed down, but also thanks to a design requiring the lift bar to extend above the top edge to unlock.

Thus, even in the case when the elastic element loses its elastic characteristics, unwanted opening of the mechanism is excluded, since in the stack the lifting beam cannot move above the upper edge of the crate, thereby preventing the locking mechanism from opening.

Fig. 14 shows an example in which two crates 100 and 100 'are mounted on top of each other. As can be seen from FIG. 14, due to the installation on top of each other, the movement of the lifting beam 106 in the crate 100 is no longer possible due to the fact that the crate 100 'is located above the crate 100. Thus, the crate 100 cannot be unlocked , and the problems described above are excluded.

Although an embodiment of the invention using a lifting beam is described in FIGS. 12-14, it should be noted that the invention is not limited to such embodiments. Conversely, other latching elements or locking elements can be used that provide for the release of the latch relative to the mating portion of the latch, and the corresponding elements can be designed in such a way that, in order to assume an unlocked position, it is necessary that at least part of the mechanism moves above the height. For example, instead of using a lifting beam, rotatable elements can be provided on both sides of the end wall, which, in the locked position, are in the state in which they are rotated downward, however, to unlock the latch, the elements are required to rotate upward so that, at least a portion of them extends beyond the upper edge of the crate, thereby achieving the same effect as described above when installing multiple crate boxes on top of each other. Although latch mechanisms or interlock mechanisms to be provided on the end walls are described in FIGS. 12-14, it should be noted that the invention is not limited to such embodiments, on the contrary, a lifting beam or other movable latching elements are provided in the side walls, and the end walls may provide the corresponding snap elements are mates.

Fourth Aspect - Coolant Inlets

Hereinafter, embodiments of the invention in accordance with a fourth aspect will be described. Conventional crates, as described above, only provide ventilation openings 110 provided for venting air through the crate. However, for various reasons, for example, to quickly cool foods inside the crates or to keep foods like vegetables, such as lettuce and the like, at a given temperature, it may also be necessary to supply coolant, preferably ice water, inside the crate. Since a coolant like ice water may also contain small particles of ice, it is not possible to introduce the required amount of coolant through the ventilation holes 110 shown in FIG. 2, on the contrary, the use of ice water or the like having corresponding particles therein, will block ventilation openings and prevent coolant from entering completely.

In accordance with embodiments of the invention in accordance with a fourth aspect, a crate is provided that may include one or more inlets to allow coolant to be introduced into the crate, one or more inlets are sized to ensure that coolant can be introduced, as required.

FIG. 15 is a side view of a crate in accordance with embodiments of the fourth aspect of the invention. FIG. 15 shows a side wall 108a similar to the side wall shown in FIG. 2. The side wall 108a comprises a stiffener 116 and ventilation holes 110. In addition, three inlets 200a-200c are provided, the first inlet 200a being provided in the upper left corner of the side wall 108a, next to the stiffener 116. Similarly, a second inlet 200b is provided in the upper right corner of the side wall 108a. A third inlet 200c is provided in a central position of the side wall 108a, near the bottom edge 124 of the side wall 108a, or near the bottom 102.

Fig. 16 shows a similar construction as in Fig. 15, except that the side wall 108a has a construction as shown in Fig. 4. The stiffener 116 has two n-shaped sections and one U-shaped section between them, and the inlets 200a and 200b are arranged so as to be at the upper end of the n-shaped sections of the stiffener 116 at a distance from the lower edge 124 of the side wall 108a. A third inlet 200c is provided at the bottom of the U-shaped portion of the stiffener 116 near the bottom edge 124 of the side wall 108a.

The location of the inlet 200a-200c, as shown in FIGS. 13 and 14, may be preferable since the inlets 200a and 200b may be larger than the inlet 200c and are provided close to the stiffeners, thereby eliminating any reduction in the structural integrity of the side walls due to the provision of inlets having a size larger than that of ventilation openings.

In accordance with embodiments, one or more inlets 200a-200c are provided with a mesh having a mesh size that is configured such that particles provided in the coolant can pass through the mesh without blocking the inlet. Although FIGS. 15 and 16 show embodiments of a fourth aspect of the invention having three inlets, it should be noted that the invention is not limited to such a design. On the contrary, the number of inlets can be freely selected depending on the needs, for example, only one or two inlets, or more than three inlets can be provided. Also, in accordance with embodiments of the invention, inlets may, alternatively or additionally, be provided at the end walls.

By means of embodiments of the fourth aspect of the invention, it is ensured that sufficient cooling liquid, such as ice water, can be introduced into the crates even when they are stacked on top of one another, since, for example, when tare crates are mounted on top of one another on a euro pallet, three tare drawers are located side by side in two rows, while their side walls are located next to each other. Thus, the crates in the center of the stack have side walls located next to the corresponding side walls of the respective outer crates, so when liquid is used relative to the outer crates with sufficient volume, it will also pass due to the large inlet into the crate. The same is true for configuration 5 below, since it can be used in the USA and as shown in Figure 3. Tare boxes 100a-100c are provided with their side walls adjacent to each other, thereby allowing the coolant to flow in the manner just described. For the other two crates 100d and 100e, coolant can easily be introduced through their side walls facing the outside of the stack.

Thus, by means of embodiments of the fourth aspect of the invention, a sufficient flow of coolant is ensured by providing an intake in accordance with embodiments of the invention.

In the above description of the invention, various embodiments of various aspects of the crate have been described separately. However, embodiments of the invention are not limited to crates comprising only one of four aspects; rather, embodiments of the invention also relate to a crate comprising one or more, or all aspects described above. In other words, embodiments of the invention can provide a crate containing one or more of the stiffeners in accordance with the first aspect, movable hinges in accordance with the second aspect, a latch mechanism in accordance with the third aspect, and a coolant inlet in accordance with the fourth aspect.

The above embodiments are only illustrative of the principles of the present invention. It should be understood that modifications and changes to the arrangements and details described herein will be apparent to those skilled in the art. Therefore, it is intended to be limited only by the scope of the forthcoming claims, and not by the specific details presented by describing and explaining the embodiments here.

Claims (9)

1. A crate containing:
bottom (102);
two end walls (106a, 106b); and
two side walls (108a, 108b),
wherein at least one of the end and side walls comprises a plurality of inlets (200a-200c) for introducing coolant into the container,
each side wall (108a, 108b) contains the first and second lateral edges (118, 120) located next to the corresponding end walls (106a, 106b), the lower edge (124) located near the bottom (102), and the upper edge (122) located at a distance from the bottom (102),
characterized in that
the specified at least one of the end and side walls contains many ventilation holes (110), while the inlets (200A-200C) have a size larger than that of the ventilation holes,
the side wall (108a, 108b) further comprises a continuous stiffener (116; 126) stiffening parallel to the first and second lateral edges (118, 120) and parallel to the upper edge (122),
the first inlet (200a) of the plurality of inlets is made on the left portion of the side wall (108a, 108b) at a distance from the lower edge (124) with a part of the continuous stiffening element (116; 126) between the first inlet (200a) and the first lateral edge (118) as well as the top edge (122), and
the second inlet (200b) of the plurality of inlets is made on the right side wall side (108a, 108b) at a distance from the lower edge (124) with a part of the continuous stiffening element (116; 126) of the stiffness between the second inlet (200b) and the second lateral edge (120) as well as the upper edge (122). 2. A crate according to claim 1, in which at least two opposite walls contain each of a plurality of inlets (200a-200c). 3. A crate according to claim 2, in which each of the side walls (108a, 108b) contains a plurality of inlets (200a-200c). 4. The crate according to claim 1, in which the continuous stiffening element (126) contains a U-shaped section (126a, 126c, 126d) in the Central region, passing towards the lower edge (124),
the first inlet (200a) is made on the left side wall side (108a, 108b) at a distance from the lower edge (124) with a part of the continuous stiffening element (126) between the first inlet (200a) and the first lateral edge (118), the upper edge (122) and the central region,
moreover, the second inlet (200b) is made on the right side wall side (108a, 108b) at a distance from the lower edge (124) with a part of the continuous stiffening element (126) between the second inlet (200b) and the second lateral edge (120), the upper edge ( 122) and the central region. 5. A crate according to claim 4, in which the third inlet (200c) is made in the central region at a distance from the upper edge (122) and with a part of the continuous stiffener between the third inlet (200c) and the lower edge (124), the left section and right section. 6. The crate according to claim 5, in which the third inlet (200c) is smaller than the first and second inlets. 7. The crate according to claim 1, in which one or more inlets (200a-200c) contain a grid. 8. The crate according to claim 1, wherein the crate is made of plastic. 9. A crate according to claim 1, wherein the crate is provided for storing and / or transporting food products, for example fruits, vegetables, meat and the like.

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