CZ36548U1 - Multi-tiered plastic vermicomposter - Google Patents

Description

Field of technology

Stackable and nestable plastic containers

Current state of the art

There is an abundance of plastic containers on the market today, in many different shapes and designs depending on what the container is intended for.

In general, it is advantageous for the containers to be at least partially nestable, thereby saving space and costs for transporting and storing such containers. Since all goods are now transported long distances, the size of the product stack is critical and the final product can become very expensive.

This problem is essential for containers where stacking is desired for the final product, i.e. the containers do not fit into each other, they are not nestable, but the upper container is seated on the upper edge of the lower container. Such an arrangement of containers is applicable, for example, to the floors of a vermicomposter. With the vermicomposter, it is also desirable that the containers are stacked tightly on top of each other, without gaps through which moisture or odors could escape from the vermicomposter. A concrete example of stacked containers can be the Urbalive vermicomposter from Plastia, which is shown in Fig. 1A and 1B.

For products that are made up of multiple containers stacked on top of each other, putting the containers inside each other for the purposes of transport and storage is excluded, which entails increased costs. A stackable container must have a frame, step or other mechanism in its upper edge/opening that allows the upper container to be stacked on the lower container. At the same time, it is this stacking mechanism that in most cases makes it impossible to insert containers into each other.

There are stackable containers on the market that solve this problem. One of them is a stackable plastic basket, which has pull-out pawls in the corners of its bottom, which - if they are extended, allow the baskets to be stacked on top of each other. If the packs are inserted, the baskets can be inserted into each other. A plastic basket with stackable pawls is shown in Figures 2A and 2B.

Another solution for containers that can be stacked on top of each other and can be inserted into each other at the same time is the asymmetrical design of containers with an asymmetric stacking step, where containers with the same orientation can be inserted into each other and containers that are oppositely oriented can be stacked on top of each other. An example of such a container from the company TBA Plastové obala s.r.o. show Figs. 3A to 3C.

However, none of these variants of stacking containers on top of each other and inserting them into each other is suitable for the floors of the vermicomposter, as a gap is created between the stacked floors of the containers, which would cause the material to fall out of the composter and the escape of earthworms, moisture and odors.

The essence of the technical solution

A multi-tiered plastic vermicomposter was produced, the tiers of which fit one on top of the other without gaps, the individual tiers of the vermicomposter can be inserted into each other for transport purposes, which saves space and costs for transportation and storage, and at the same time the individual tiers of this vermicomposter are stackable. The stacking of individual containers on top of each other, i.e. the tiers of the vermicomposter, provides a closed interior space of the vermicomposter, and the vermicomposter can thus work properly - without material falling out of the vermicompostor and without leakage of moisture and odors.

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This goal is achieved with a removable plastic stacking frame for stacking the vermicomposter containers/tiers on top of each other.

The removable frame narrows the top opening of the stackable container, allowing another container to be "sat" on top of it. Thanks to the fact that the frame is integral and copies the shape of the container, it ensures the closure of the space between the individual levels of the vermicompostor. If the frame is placed on the top edge of the container, it allows the containers to be stacked on top of each other. If the frame is removed from the container and placed on or under the container, it enables the containers to be easily inserted into each other, transported and stored with minimal space requirements.

The frame is attached to the container in a demountable manner, preferably pushed on or snapped on.

The stackable removable frame is made of plastic. With its outer shape, the frame copies the shape of the edge of the lower stacked container, and with its inner shape, it copies the shape of the bottom of the upper stacked container. When viewed from above, the outer circumference of the frame is greater than the circumference of the free opening of the lower stacking container, which ensures that the frame rests on the upper edge of the lower stacking container. See Fig. 11. And at the same time, the inner circumference of the frame when viewed from above is smaller than the outer circumference of the bottom of the upper stacked container, which ensures that the upper stacked container is placed on the frame and does not fit into the lower stacked container.

The frame is placed on the upper edge of the lower stacked container and a good stacked container is built on the frame, whereby the containers are stacked on top of each other. If the frame is removed from the lower container, the good container fits into the lower container, thereby nesting the containers.

The frame preferably has a mechanism for being placed on the upper edge of the stacked container. Advantageously, the mechanism is a groove, the width of which corresponds to the thickness of the edge of the lower plastic container, and the groove also copies the shape and size of the edge of the lower plastic container. Advantageously, the groove is provided with protrusions, preferably return hooks, pointing in the direction of the groove.

In such an embodiment, the lower container is preferably provided with a reinforcement on its edge, which fits into the groove and is fixed in the groove by means of protrusions.

Advantageously, in addition to the stacking function, the frame also has a reinforcing function. Stacked containers can be made thin-walled, with low strength, which saves on the cost of their production. In such a case, the frame is preferably profiled or ribbed for greater reinforcement.

This technical solution solved the problem of the large volume occupied by containers stacked on top of each other, which entailed high costs for transportation and storage. The material consumption for making a plastic container with a removable stacking frame is the same as the material consumption for making a container with a stacking frame already incorporated, but the cost of shipping and storing the container is reduced if the frame can be removed.

The height of containers placed inside each other, i.e. for the purposes of transport or storage, of course depends on their shape, especially on the slope of their walls. If we assume that the container is smooth and does not have any reinforcing ribs or stacking frame, the stackability/stackability of the containers can be summarized as follows: The closer the shape of the containers to the shape of a cylinder or cuboid, the more difficult the containers are to insert into each other and the higher the transport height of containers. The closer the shape of the containers is to a cone or pyramid, the easier the containers are to fit into each other and the lower the transport height of the containers. The situation changes if the container contains reinforcing ribs or a frame that complicates stacking. In the event that stacked containers contain reinforcing ribs, the upper stacked container usually sits on the ribs of the lower stacked container, however, nesting of containers is still possible. In the event that the stacked containers contain non-removable stacking elements, for example a stacking step or a frame, inserting the containers into each other is completely excluded due to the nature of the stacking elements, which only allow the containers to be stacked on top of each other.

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A specific design and comparison of stackable containers with a built-in and with a removable frame are shown in Figs. 4 to 6. For simplicity, only two containers are shown, i.e. the lower and upper stacked container. The concepts of lower/upper container are preserved even if it is a stack of more than two containers, as they always describe the relationship of two containers above each other, between which a stacking frame is placed.

In one particular demonstrative embodiment, the vermicomposter consists of two containers and one stacking frame. The stacked containers are both identical, circular, and their height is 12 cm. The height of the frame is 2 cm. The inner diameter of the container at the opening is 30 cm and the outer diameter at the bottom is 27 cm. So the container is slightly conical. When viewed from above, the stacking frame has the shape of an annulus and has a groove on its underside for mounting on the bottom stacked container, similar to Fig. 12. The height of the frame after mounting on the container is approx. 0.2 cm and is neglected for this calculation. The inner diameter of the stacking frame is 25 cm. If we transport containers with a stacking frame attached, two containers stacked on top of each other have a height of 12+12 cm = 24 cm - see Fig. 6. However, if we remove the stacking frame from the bottom stacked container and place two containers inside each other and place their stacking frame on top of them , we reach a height of 12+12-8+2 = 18 cm - see Fig. 5, where 8 cm is the depth of immersion of one container into the other. The volume of the box for two containers with built-in stacking frames stacked on top of each other is 30 x 30 x 24 cm = 0.0216 m ³ and the volume of the box for two containers with removable stacking frames stacked on top of each other is 30 x 30 x 18 cm = 0.0162 m ³ . It may seem that the saving of space is not great, but after further calculations, it turns out that the space occupied by 6 boxes of containers stacked on top of each other can fit 8 boxes of containers with a removable frame inserted inside each other. That is two levels of boxes, i.e. 24 boxes, more on one pallet with a loading height of 144 cm.

In the event that the stacking frame was snapped onto the upper container for packaging purposes and the latter was inserted into the lower container, the height of the box would be even 12+12-8 = 16 cm, the volume of the box 0.0144 m ³ and a saving on the pallet of two floors at a height of 96 cm, by 4 floors, i.e. 48 boxes at a loading height of 192 cm.

Clarification of drawings

Giant. 1A: State of the art, Urbalive vermicomposter, Plastia, layer with stacking post

Giant. 1B: State of the art, Urbalive vermicomposter, Plastia, stackable tiers for transport and use

Giant. 2A: State of the art, plastic basket with extendable pawls in the corners of its bottom (source: https://www.oriondomacipotreby.cz/kosik-nesta-stohovatelny-38x33x12-7-cm-731195)

Giant. 2B: State of the art, two plastic baskets with extendable pawls in the corners of the bottom stacked on top of each other (source: https://www.oriondomacipotreby.cz/kosik-nesta-stohovatelny-38x33x12-7-cm-731195)

Giant. 3A: State of the art, asymmetric plastic containers with a stacking step, folded in opposite orientation to each other, side view (source: https://www.tbaplast.cz/stohovatelne-prebky)

Giant. 3B: State of the art, asymmetric plastic containers with a stacking step, stacked in the same orientation on top of each other (source: https://www.tbaplast.cz/stohovatelne-prepravky)

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Giant. 3C: State of the art, asymmetric plastic containers with a stacking step, folded in opposite orientation to each other, front view (source: https://www.tbaplast.cz/stohovatelne-prebky)

Fig. 4: Plastic container and its reinforcing plastic frame, section

Giant. 5: Two plastic containers from Fig. 4 stacked without frames, frames separately above the containers, section

Giant. 6: Two plastic containers from Fig. 4 stacked and with frames, section

Giant. 7: Comparison of stacking variants according to Fig. 4 to 6

Giant. 8A: Concrete example of vermicomposter packaging, stacking together for transport

Giant. 8B: Concrete example of vermicomposter packaging, stacking on top of each other for use

Giant. 9: Detachable frame for a rectangular top rim container with rounded corners when viewed from above

Giant. 10: Compatible container for the frame according to Fig. 9 in a top view

Giant. 11: Removable frame placed on the container when projected from above, when the frame covers the upper edge of the container and the lower edge of the bottom of the container

Giant. 12: Removable frame with a groove for fitting to the upper edge of the container, in section

Examples of implementing a technical solution

Example 1

A plastic vermicomposter consisting of three identical containers 2 and two stacking frames 1 was produced. Containers 2 had the shape of a rectangle with rounded corners in the projection from above, where the size of the upper opening of container 2 was as follows: length 40 cm, width 25 cm, height of container 2 was 15 cm and the size of the bottom of container 2 was as follows: length 37 cm and width 23 cm. The wall thickness of vessel 2 was 0.3 cm. The removable stacking frame 1 copied the shape of the container 2 in its shape, the width of the frame 1 was 5 cm when projected from above and the height of the frame 1 was 2 cm, while the frame 1 was provided on its lower side with a mechanism 13 for being placed on the upper edge 23 of the container 2, which there was a groove 1 cm deep, which in its shape and size copied the upper edge of the lower container 2, 21, i.e. it had a thickness of 0.3 cm.

The composter with the dimensions described above was assembled into a box for transport and storage in such a way that three containers 2 were inserted into each other, one stacking frame 1 was snapped onto the upper container 2, 22 and a second stacking frame 1 was loosely placed on it. The height of the package with with firmly incorporated stacking frames on the containers would be 3 x (15 + 1) = 48 cm, where 1 cm is the height of the stacking frame 1 after being slotted onto the container 2. However, the height of the package with the removable stacking frames 1 was only (3x15) - (2 x 10) + 1 + 2 = 28 cm, where 10 cm is the immersion of containers 2 into each other, 1 cm is frame 1 placed on container 2 and 2 cm is free frame 1 placed on the first frame 1 freely.

After unpacking the individual components of the composter, the containers 2 were removed from each other and the free frame 1 was clipped onto one of the two free containers 2. Then the containers 2, 21 with the stacking frames 1 installed were stacked on top of each other, while the container 2 without the frame 1 was located at the very top as the last and then fitted with a lid.

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Example 2

A plastic vermicomposter consisting of five identical containers 2 and four removable stacking frames 1 was produced. Containers 2 had the shape of a square with rounded corners in the projection from above, when container 2 had an opening narrowed by 0.5 cm compared to the walls of container 2, when the dimensions of the walls of container 2 before narrowing were as follows: length 38 cm, width 38 cm, the size of the top opening of container 2 was as follows: length 37 cm, width 37 cm, the height of container 2 was 15 cm, and the size of the bottom 24 of container 2 was as follows: length 36.5 cm and width 36.5 cm. Similarly shaped containers 2 are shown in Fig. 8A and 8B. The wall thickness of vessel 2 was 0.2 cm. The shape of the stacking frame 1 copied the shape of the container 2, while the frame 1 dimensionally copied the outer width of the walls of the container 2 under the narrowing, the width of the frame 1 was 4 cm when viewed from above, and the height of the frame 1 was 2 cm. The frame 1 was provided on its lower side with a groove for fitting on the upper edge 23 of the container 2, when the groove was offset from the outer edge 12 of the frame 1 by 0.5 cm and was 1.5 cm deep. The shape of the groove copied the upper edge 23 of container 2 and was equipped with return hooks. The groove was 0.4 cm thick and the hooks extended into the free space of the groove by 0.15 cm. After placing the stacking frame 1 on the container 2, 21, the outer edge 12 of the frame 1 is aligned with the walls of the container 2 due to the narrowing of the upper opening 23 of the container 2. The frame 1 placed on the container 2 appears spatially clean and does not protrude over the walls of the container 2.

The composter of the dimensions described above was assembled into a box for transport and storage in such a way that five containers 2 were inserted into each other, one stacking frame 1 was snapped onto the upper container 22 and three free stacking frames 1 were placed loosely on it.

After unpacking the individual components of the composter, the containers 2 were removed from each other and the free frames 1 were snapped onto three of the four free containers 2, 21. Then the containers 2, 21 with the stacking frames 1 were stacked on top of each other, while the container 2, 22 without the frame 1 was situated at the very top as the last one and then fitted with a lid.

Example 3

A plastic vermicomposter was made consisting of two identical containers 2 and one stacking frame 1. Containers 2 had the shape of a circle in the projection from above, where the diameter of the upper opening of container 2 was 30 cm, the height of container 2 was 10 cm and the diameter of the bottom of container 2 was 25 cm. The wall thickness of vessel 2 was 0.2 cm. The removable stacking frame 1 had an annular shape with an inner diameter of 22 cm and an outer diameter of 37 cm and a thickness of 0.4 cm.

A composter of the dimensions described above was assembled into a box for transport and storage so that the containers 2 were inserted into each other, the stacking frame 1 was snapped onto the upper container 2, 22. The height of the package with the stacking frame firmly incorporated on the containers would be 10 + 10 + 0.4 = 20.4 cm. However, the height of the package with the removable stacking frame 1 was only 10 + 10 + 0.4 - 8 = 12.4 cm, where 8 cm is the depth of immersion of one container into the other.

After unpacking the individual components of the composter, the containers 2 were removed from each other and the free frame 1 was placed on the lower container 21. Then the upper container 22 without the frame 1 was placed on the frame 1 placed on the lower container 21.

Industrial applicability

Stacking, storage and transport of plastic vermicompost containers with a stacking frame nested inside each other.

Claims (5)

PROTECTION CLAIMS 1. A multi-level plastic vermicomposter, characterized by the fact that it contains n containers (2) that can be inserted into each other and n-1 removable stacking frames (1), when n > 1, and the containers (2) are conical, when the circumference of the bottom (24) of the container (2) is smaller than the circumference of the upper edge (23) of the container (2), the removable stacking frame (1) when viewed from above, copies the upper edge (23) of the lower container (21) with its external shape and overlaps it; the outer circumference (12) of the stacking frame (1) is larger than the circumference of the upper edge (23) of the lower container (21), and at the same time, with its internal shape, the stacking frame (1) copies the edge of the bottom (24) of the container (22), which it also overlaps; and the inner circumference (11) of the stacking frame (1) is smaller than the circumference of the bottom (24) of the upper container (22). 2. A multi-level plastic vermicomposter according to claim 1, characterized in that the removable stacking frame (1) contains a mechanism (13) for mounting on the lower container (21). 3. Multi-level plastic vermicomposter according to claim 2, characterized in that the mechanism (13) for deployment is a groove, the inner width of which is the same as the outer thickness of the upper edge (23) of the lower container (21). 4. A multi-level plastic vermicomposter according to claim 3, characterized in that the groove contains protrusions or return hooks pointing towards the groove. 5. Multi-level plastic vermicomposter according to claim 1, characterized in that the container (2) and/or the stacking frame (1) contains reinforcements in the form of ribs or reinforced walls.