The present invention relates to a cyclone separation system for separating live insects from an air stream. The invention also relates to the cyclone separation system provided with an insects transport device for provision of live insects into the cyclone separation system. In a further aspect the present invention relates to a method of separating live insects from an air stream, and in particular a method of providing batches of live insects.
US patent publication US 2018/0049418 A1 discloses a variable-scale computer operated Insect Production Superstructure Systems (IPSS) for the production of insects for human and animal consumption, and for the extraction and use of lipids for applications involving medicine, nanotechnology, consumer products, and chemical production with minimal water, feedstock, and environmental impact. An IPSS may comprise modules including feed stock mixing, enhanced feedstock splitting, insect feeding, insect breeding, insect collection, insect grinding, pathogen removal, multifunctional flour mixing, and lipid extraction. In an embodiment, an insect feeding module is in fluid communication with an insect evacuation module comprising separator that may be a cyclone for separating insects from a gas.
U.S. patent publication U.S. Pat. No. 5,594,654 discloses an automated system developed to count and package beneficial insect larvae or eggs and includes a funnel-shaped container which sits in the top portion of a sensor head and a turntable with multiple containers located below the sensor head, for collecting larvae or eggs as they drop through the sensor head. The system accurately records the number and time stamps each insect larva or egg detection as they drop through a sensor head.
The present invention aims to provide a cyclone separation system for separating live insects from an air stream, such as neonate larvae, wherein the cyclone separation system allows for efficient and reliable batch wise discharge of live insects from the cyclone separation system whilst keeping the live insects alive and preventing that the live insects stick or adhere to internal walls of the cyclone separation system. The cyclone separation system is ideally suited for being integrated in an automated live insect processing facility.
According to the present invention, a cyclone separation system of the type defined in the preamble is provided, wherein the cyclone separation system comprises a main cyclone chamber having a top chamber part and a conical shaped bottom chamber part. The top chamber part is connected to one or more intake channels each of which is arranged for connection to a primary air source providing an air stream laden with live insects, and wherein the bottom chamber part is connected to a discharge nozzle that comprises a discharge end having a main discharge conduit for discharging the (separated) live insects from the cyclone separation system. The discharge end of the discharge nozzle comprises an air injection member that is arranged for connection to a secondary air source and wherein the air injection member is configured to inject air back into the discharge nozzle.
According to the present invention, the air injection member of the discharge end is configured for injecting air back into the discharge nozzle, i.e. in upstream direction, so that separated live insects in the discharge nozzle and moving in a direction toward the discharge end, i.e. in downstream direction, can be stopped and air suspended/cushioned by the injected air. Through injection of back/upstream flowing air into the discharge nozzle the discharge of live insects can be stopped and as such the air injection member acts like a controllable air valve. Furthermore, the injected air allows live insects to be air suspended/cushioned, e.g. pushed in upstream direction, thereby preventing the live insects from sticking to inner walls of the discharge nozzle and a such prevent clump formation of live insects that could potentially block the discharge nozzle.
Another advantage of the air injection member is that intermittent, time limited air injections back into the discharge nozzle can be performed, thereby achieving intermittent discharge of live insects between two successive air injections. The time interval between two successive air injections then determines a batch of discharged live insects that can be collected and transferred for further processing. Transferring such a collected batch of live insects is achieved during such a time limited air injection.
In an embodiment, the air injection member of the discharge end comprises an air chamber and an air injection conduit (i.e. a first air injection conduit) fluidly (e.g. gaseous) connecting the air chamber and the main discharge conduit of the discharge end. The air injection conduit is configured to provide an injected air flow in a direction back into the discharge nozzle when air is pushed through the air injection conduit. In this embodiment the air injection conduit allows for the injected air flow to be directed into the discharge nozzle in upstream fashion such that live insects are effectively suspended in air, thereby stopping the discharge. For example, in an embodiment the air injection conduit is arranged at an injection angle smaller than 60° degrees with respect to a longitudinal axis of the discharge nozzle, so that the air flow being injected does indeed move in a direction back into the discharge nozzle.
According to the present invention, it is possible to utilize a plurality of air injection conduits that are configured to provide an injected air flow in a direction back into the discharge nozzle. For example, the air injection member of the discharge end may comprise a further or second air chamber and a further or second air injection conduit fluidly (e.g. gaseous) connecting the further/second air chamber and the main discharge conduit of the discharge end, wherein the further/second air injection conduit is arranged to provide a further/second injected air flow in a direction back into the discharge nozzle. Like the air injection conduit (i.e. the first air injection conduit), the further/second air injection conduit allows for a further/second injected air flow to be directed into the discharge nozzle in upstream fashion such that live insects are effectively air suspended or air cushioned for further stopping the discharge of live insects.
in an embodiment the further/second air injection conduit is arranged at a further/second injection angle smaller than 60° degrees with respect to the longitudinal axis of the discharge nozzle, so that the further/second air flow being injected through the further/second air injection conduit does indeed move in a direction into the discharge nozzle.
Utilizing a plurality of injection conduits for injecting air into the main discharge conduit allows for further optimization of injected air flow. For example, in an embodiment the aforementioned first and further/second air injection conduits may be arranged on opposite sides of the main discharge conduit. This embodiment then allows two separate air flows to be injected back into the discharge nozzle for an overall improved flow distribution of injected air throughout the discharge nozzle. This in turn allows for improved distributed air suspension/cushioning of live insects for stopping the discharge thereof.
Since the air injection member is configured for connection to a secondary air source, it may be advantageous to minimize and simplify the number of physical connections of the secondary air source to the air injection member. To that end an embodiment may be considered wherein the first and second air chambers are arranged on opposite sides of the main discharge conduit and are fluidly (e.g. gaseous) connected to one another. That is, in this embodiment the first and second air chambers are fluidly (e.g. gaseous) coupled and may be envisaged as forming a single air chamber circumferentially encircling the main discharge conduit. Since the first and second air chambers effectively form a single air chamber, it is possible to utilize a single air inlet configured to connect to the secondary air source and wherein the single air inlet also fluidly connects to the interconnected first and second air chambers.
The present invention will be discussed in more detail below, with reference to the attached drawings, in which
As the skilled person will understand, in operation the one or more intake channels 5K carrying the air streams AK induce a main vortex in the top chamber part 3K that allows centrifugal separation of the live insects from the (combined) air streams AK. The separated live insects then follow conical inner walls of the bottom chamber part 4K toward the discharge nozzle 6K. Due to the conical shaped bottom chamber part 4K, an ascending inner vortex of “clean” air is generated that exits the top chamber part 3K through an air exit 9K arranged thereon.
As further depicted, the discharge end 7K of the discharge nozzle 6K comprises an air injection member 10K for connection to a secondary air source (not shown) and wherein the air injection member 10K is configured to inject air back into the discharge nozzle 6K.
According to the present invention, the air injection member 10K of the discharge end 7K is configured to inject air back into the discharge nozzle 6K, i.e. in an upstream direction “UK”, so that separated live insects moving downstream into the discharge end 7K, i.e. in downstream direction “DK”, can be stopped from discharging through suspension by the injected air. By virtue of injection of backward or upstream flowing air into the discharge nozzle 6K, the discharge of live insects can be stopped and as such the air injection member 10K acts as a controllable air valve allowing the main discharge conduit 8K to be opened or closed through a “wall” of upstream flowing air.
Furthermore, as the injected air effectively cushions the live insects in air, prolonged contact of live insects with inner walls of the discharge nozzle 6K is prevented. This ensures that live insects are less prone to stick to inner walls of the discharge nozzle and a such prevent clump formation therein.
As will be discussed in further detail below, another advantage of the air injection member 10K is that intermittent, time limited air injections back into the discharge nozzle 6K can be utilised for intermittent discharge of separated live insects between two successive air injections when the cyclone separation system 1K is in operation. The time interval between two successive air injections then determines a batch of discharged live insects that can be collected and transferred for further processing. Transferring a collected batch of live insects can be achieved during a subsequent air injection by the air injection member 10K.
In an embodiment, the top chamber part 3K may be further connected to an auxiliary intake channel 11K arranged to receive additional air, called “pilot air”, to further optimize vortex generation within the top chamber part 3K.
To maintain sufficient pressure and air flow within the one or more intake channels 5K, an embodiment may be provided wherein each of the intake channels 5K comprises an air amplifier unit 5aK, which is configured to provide a supplementary air stream to the air stream AK in a flow direction thereof.
It is noted that an embodiment is conceivable wherein the bottom chamber part 4K and the discharge nozzle 6K are integrated as a single piece to reduce the number of ridges at which live insects could potentially stick and clump together.
The air injection member 10K may further comprise an air inlet 14K for connecting to the secondary air source and wherein the air inlet 14K is fluidly (gaseous) connected to the main discharge conduit 8K allow air injecting back into the discharge nozzle.
Note that
In particular,
In an embodiment, the first air injection conduit 16K is arranged at an injection angle α1K, i.e. a first injection angle α1K, smaller than 60° degrees with respect to a longitudinal axis LK of the discharge nozzle 6K. The first injection angle α1K less than 60° ensures that when air is being injected into the main discharge conduit 8K through the first air injection conduit 16K, that the first injected air flow F1K is directed into the discharge nozzle 6K for air suspension/cushioning the live insects and stop discharge thereof. In specific embodiments, the first injection angle α1K may be 45° or less to ensure good back flow of injected air into the discharge nozzle 6K.
In advantageous embodiments, the first injected air flow F1K may engage an inner wall portion 17K, i.e. a first inner wall portion 17K, of the discharge nozzle 6K in parallel fashion as most live insects will descend into the bottom chamber part 4K and the discharge nozzle 6K along walls thereof. In an embodiment, the first inner wall portion 17K may be located somewhere halfway a converging section “CK” of the discharge nozzle 6K as sufficient convergence and compaction of live insects will have occurred at such a location for the first injected air flow F1K to be adequate for air suspension/cushioning separated live insects. It is noted that the skilled person will understand that the converging section “CK” may comprise various profiles of the first inner wall portion 17K and that the substantial parallel engagement of the first injected air flow F1K with the first inner wall portion 17K may occur closer or further away from the first air injection conduit 16K.
To allow for the substantial parallel engagement between the first injected airflow F1K and the first inner wall portion 17K, an embodiment is provided wherein the discharge nozzle 6K comprises the first inner wall portion 17K which is arranged, e.g. at least locally, at a wall angle β1K, i.e. a first wall angle β1K, with respect to the longitudinal axis LK of the discharge nozzle 6K. The first injection angle α1K of the first air injection conduit 16K is then substantially equal/aligned with the first wall angle β1K. In this embodiment the first inner wall portion 17K is at least locally arranged at the first wall angle β1K which substantially coincides with the first injection angle α1K. This alignment of angles α1K, β1K allows the first injected air flow F1K to engage the first inner wall portion 17K in substantial parallel fashion for good air suspension/cushioning the separated live insects as most live insects descend into the discharge nozzle 6K along inner walls thereof, e.g. the first inner wall portion 17K. This embodiment may be further clarified by imagining a tangent line T1K coinciding with the first inner wall portion 17K and wherein the tangent line T1K is at the first inner wall angle β1K. As depicted in
In an embodiment, the first air injection conduit 16K may have a width, i.e. a first width W1K, between 0.2 mm and 1 mm to allow sufficiently strong air flow back into the discharge nozzle 6K for air suspension/cushioning separated live insects. It is noted that in this embodiment a smaller first width W1K within this range will generally provide a faster first injected air flow F1K with less air usage compared to having a larger first width W1K within this range for the first air injection conduit 16K. Choosing smaller values for the first width W1K will typically lead to reduced disturbance of the air flow within the discharge nozzle 6K.
Turning to
In an embodiment, the second air injection conduit 20K is arranged at a further injection angle α2K, i.e. a second injection angle α2K, smaller than 60° degrees with respect to a longitudinal axis LK of the discharge nozzle 6K. Providing a second injection angle α2K less than 60° ensures that when air is being injected into the main discharge conduit 8K through the second air injection conduit 20K, that the second injected air flow F2K is primarily directed into the discharge nozzle 6K for air suspension/cushioning the live insects and stop discharge thereof. In specific embodiments, the second injection angle α2K may be 45° or less to ensure good back flow of injected air into the discharge nozzle 6K.
In advantageous embodiments, the second injected airflow F2K may engage a further inner wall portion 21K, i.e. a second inner wall portion 21K, of the discharge nozzle 6K in parallel fashion as most live insects will descend into the bottom chamber part 4K and the discharge nozzle 6K along inner walls thereof. In an embodiment, the second inner wall portion 21K may be located somewhere halfway the aforementioned converging section “C” of the discharge nozzle 6K as sufficient convergence and compaction of live insects will have occurred at this location for the second injected air flow F2K to be adequate for air suspension/cushioning separated live insects.
As mentioned earlier, the converging section “C” may comprise various profiles of the second inner wall portion 21K and that the substantial parallel engagement between the second injected air flow F2K and the second inner wall portion 21K may occur closer or further away from the second air injection conduit 20K.
To facilitate the substantial parallel engagement between the second injected air flow F2K and the second inner wall portion 21K, an embodiment is provided wherein the discharge nozzle 6K comprises a second inner wall portion 21K which is arranged at a further wall angle β2K, i.e. a second wall angle β2K, with respect to the longitudinal axis LK of the discharge nozzle 6K. The second injection angle α2K of the second air injection conduit 20K is then substantially equal/aligned with the second wall angle β2K. In this embodiment the second inner wall portion 21K is at least locally arranged at the second wall angle β2K which substantially coincides with the second injection angle α2K. This alignment of angles α2K, β2K allows the second injected air flow F2K to engage the second inner wall portion 21K in substantial parallel fashion for good air suspension/cushioning of the separated live insects when descending into the discharge nozzle 6K along inner walls thereof, e.g. the second inner wall portion 21K. This embodiment may be further clarified by imagining a tangent line T2K coinciding with the second inner wall portion 21K and wherein the tangent line T2K is at the second wall angle β2K. As depicted in
Further, the air injection member 10K may comprise an air inlet 14K for connecting the air injection member 10K to the secondary air source (not shown) and wherein the air inlet 14K is fluidly (gaseous) connected to the main discharge conduit 8K allowing air injection back into the discharge nozzle 6K. In an exemplary embodiment, the air inlet 14K may be fluidly (gaseous) connected to the air chamber 15K, i.e. the first air chamber 15K, thereby allowing for the injected air flow F1K, i.e. the first injected air flow F1K, in a direction back into the discharge nozzle 6K. In a further exemplary embodiment, the air injection member 10K may comprise a further air inlet (not shown), i.e. a second air inlet, which is fluidly (gaseous) connected to the second air chamber 19K, thereby allowing for the second injected air flow F2K in a direction back into the discharge nozzle 6K.
By using a first and second air inlet it is possible to provide the first and second injected air flows F1K, F2K through the first and second air injection conduits 16K, 20K.
From
By fluidly (gaseous) connecting first and second air chambers 15K, 19K, an embodiment is conceivable wherein the first and second air chambers 15K, 19K form a circumferentially arranged air chamber encircling the main discharge conduit 8K. Such a circumferentially arranged air chamber allows for further equal air distribution throughout the air injection member 10K toward the first and second air injection conduits 16K, 20K.
In line with an opposing arrangement of the first and second air chambers 15K, 19K, and as depicted in
Turning to
In an embodiment, the second air injection conduit 20K may have a width W2K i.e. a second width W2K, between 0.2 mm and 1 mm to allow sufficiently strong air volume flowing back into the discharge nozzle 6K for air suspension/cushioning of separate live insects. It is noted that in this embodiment a smaller second width W2K within this range will generally provide a faster second injected airflow F2K with less air usage compared to having a larger second width W2K in this range for the second air injection conduit 20K. Choosing smaller values for the second width W2K will typically lead to less disturbance of the air flow within the discharge nozzle 6K.
When the first and second air injection conduits 16K, 20K are arranged on opposite sides of the main discharge conduit 8K, then this implies that the first and second discharge conduit wall portions 18K, 22K, at which the first and second air injection conduits 16K, 20K terminate, are also oppositely arranged with respect to the main discharge conduit 8K.
To further elaborate on the indicated cross sections “III A” and “IV A” in
From
From
From
In an embodiment, as exemplified in
In an advantageous embodiment, the first and second air injection conduits 16K, 20K are arranged to provide a back flowing vortex V exhibiting a rotational direction identical to a rotational direction of the main vortex in the top chamber part 3K which is responsible for centrifugal separation of the live insects from the air streams A. Having identical rotational directions of the main vortex and the back flowing vortex V prevents that rotationally moving live insects descending into the discharge nozzle 6K could potentially stop rotating by an oppositely rotating back flowing vortex V. As a result, live insects could come into prolonged contact with inner walls of the discharge nozzle 6K increasing the chance of clump formation.
In an embodiment, the slit shaped first and second air injection conduits 16K, 20K may each have a length Ls of at most 50% of a width WcK of the main discharge conduit 8K, thereby allowing the first and second injected air flows F1K, F2K to generate a back vortex V within the discharge nozzle 6K through appropriate placement of the slit shaped first and second air injection conduits 16K, 20K. For example, by lateral/sideways offsetting slit shaped first and second air injection conduits 16K, 20K, and limiting the length Ls of each of these conduits 16K, 20K to at most 50% of the width WCK of the main discharge conduit 8K, then a stable and uniform back flowing vortex V can be generated through the first and second injected air flows F1K, F2K for optimal air suspension/cushioning of live insects. Of course, in further embodiments it would be possible that the slit shaped first and second air injection conduits 16K, 20K may each have a length LS of more than 50% of the width WCK of the main discharge conduit 8K, thereby allowing for further improvements of the first and second injected air flows F1K, F2K if necessary. In even further embodiments the slit shaped first and second air injection conduits 16K, 20K may each have a length LS between 0 and 100% of the width WCK of the main discharge conduit 8K in case full design freedom of each of the conduits 16K, 20K is required for achieving a specific back flowing air profile into the discharge nozzle 6K.
For example,
comprising a substantially rectangular main discharge conduit 8K. Both the first and second air injection conduits 16K, 20K are seen to be slit shaped conduits, wherein the first air injection conduit 16K is arranged on a left side of a lateral centreline “YK” of the main discharge conduit 8K whereas the second air injection conduit 20K is arranged on a right side of the centreline “YK”. So based on the view provided in
Furthermore, since the discharge nozzle 6K changes from a circular geometry at the intake end 12K toward a rectangular geometry at the discharge end 7K, enhances the generation of a back flowing vortex V as the first and second injected air flows F1K, F2K engage and follow a curvature of the first and second inner wall portions 17K, 21K.
As further depicted in
As mentioned earlier, in an embodiment the discharge nozzle 6K may have a circular intake end 12K and a substantially rectangular discharge end 7K, i.e. with a substantially rectangular main discharge conduit 8K.
This not only facilitates generation of a back flowing vortex V as explained above, but having a substantially rectangular main discharge conduit 8K is also advantageous for reasons related to reliably counting the number of live insects being discharged as explained below.
In particular,
For example, in
Now, to facilitate accurate and reliable operation of the camera based counting system 23K, in an advantageous embodiment the main nozzle discharge conduit 8K is rectangular such that the live insects discharged there through form a relatively wide but thinner “curtain” or “cloud” of live insects. That is, having a wider and thinner stream of live insects discharged from the discharge nozzle 6K reduces the chance that live insects closer to a camera block the view of live insects behind them. So by ensuring that the field of view FVK extends through a widest side of the rectangular main discharge conduit 8K, facilitates accurate counting of discharged live insects.
In a further advantageous embodiment, the camera based counting system 23K defines a planar triangular field of view FVK and wherein the main discharge conduit 8K comprises a trapezium shaped cross section having two opposing non-parallel sides 25K, 26K each of which is parallel to an edge 27K of the planar triangular field of view FVK. This ensures that the entire trapezium shaped cross section of the main discharge conduit 8K can be monitored by the camera based counting system 23K and that no blind corners of the main discharge conduit 8K exist through which live insects may be discharged undetected.
Of course, in case the main discharge conduit 8K is rectangular, i.e. all sides thereof are perpendicular, then a wider triangular field of view FVK would be needed to avoid blind corners of the main discharge conduit 8K.
In an embodiment, the camera based counting system 23K comprises a light source 28K arranged opposite the main discharge conduit 8K for easier detection through illumination of live insects passing through the field of view FVK. In a further embodiment the light source 28K may be an elongated, line light source 28K, allowing substantially equal light intensity along the cross section of the main discharge conduit 8K. In a further embodiment the camera based counting system 23K may comprise a line scanning camera allowing for the aforementioned planar, triangular field of view FVK.
Referring to
In particular,
In an exemplary embodiment, in order to achieve such cross-wise flow as depicted in
It is worth noting that, in further embodiments, larger first injection angles α1K are also conceivable, e.g. between 60° and 90°, in order to achieve impingement of the first injected air flow F1K on the opposing deflection conduit wall portion 22aK (22K) so that a cross-wise flow F1K, F1aK is obtained for temporarily blocking discharge of live insects from the main discharge conduit 8.
Referring to
In further embodiments, larger second injection angles α2K are conceivable, e.g. between 60° and 90°, in order to achieve impingement of the second injected air flow F2K on the opposing first conduit wall portion 18K, so that a cross-wise flow is obtained for temporarily stopping live insects from being discharged from the main discharge conduit 8K.
Achieving deflected first and second injected air flows F1 K, F2K may be advantageous in an embodiment wherein slit shaped first and second air injection conduits 16K, 20K are arranged on opposite sides of the main discharge conduit (8K) and are laterally/sideways offset in opposite direction. This would then result in offset deflected air flows along the main discharge conduit 8K for temporarily stopping discharge of live insects.
In an embodiment mentioned earlier, the slit shaped first and second air injection conduits 16K, 20K may each have a length LsK of at most 50% of a width WCK of the main discharge conduit 8K. Then by offsetting the slit shaped first and second air injection conduits 16K, 20K along the main discharge conduit 8K allows a full air block to be achieved thereof.
In an advantageous embodiment it is also possible to utilize a single slit shaped air injection conduit, e.g. only using a slit shaped first air injection conduit 16K as shown in
Instead of using a single first air injection conduit 16K along the main discharge conduit 8K as exemplified in
In the depicted embodiments, the first air injection conduit 16K may comprise a plurality of first conduit sections 16aK and wherein the second air injection conduit 20K may comprise a plurality of second conduit sections 20aK, wherein the plurality of the first and second conduit sections 16aK, 20aK are laterally/sideways offset in alternating manner along a width WCK of the main discharge conduit 8K. In this embodiment the first and second conduit sections 16aK, 20aK may provide an alternating arrangement of opposing first and second injected air flows F1K and F2K as shown in
Referring again to
To further prevent accumulation of live insects, an advantageous embodiment is provided wherein each of the two auxiliary air injection conduits 29K is arranged at an auxiliary injection angle γ1K between 10° and 50° degrees with respect to the longitudinal axis LK of the discharge nozzle 6K. In this embodiment the auxiliary injection angle γ1K of the two auxiliary air injection conduits 29K may be chosen to prevent separation of the two auxiliary injected air flows G1K, G2K from an inner surface 31K of the shortest sides SsK, which inner surface 31K extends from the shortest sides SsK into the funnel shaped passage 13K. Therefore, when the two auxiliary injected air flows G1K,G2K remain attached to the inner surface 31K improves air flow there along and as such prevent accumulation of live insects at the inner surface SsK of the shortest sides SsK of the main discharge conduit 8K. In an exemplary embodiment the auxiliary injection angle γ1K is about 45° degrees, or even 35° degrees, to prevent separation of the two auxiliary injected air flows G1K, G2K from the inners surface 31K of the shortest sides SsK of the main discharge conduit 8K.
Referring shortly to
However, when live insects are discharged into the container 24K, a number of the live insects may not be discharged parallel to the longitudinal axis LK of the discharge nozzle 6K. That is, a particular number of live insects could potentially be discharged from the main discharge conduit 8K in a diagonal manner as shown in
According to the present invention, to prevent live insects from missing the container 24K, an embodiment is provided wherein the discharge nozzle 6K further comprises a discharge guiding member 32K mounted to/underneath the discharge end 7K of the discharge nozzle 6K. The discharge guiding member 32K comprises an expanding guiding channel 33K fluidly coupled to the main discharge conduit 8K for receiving live insects when the cyclone separation system 1K is in operation. In this embodiment the guiding channel 33K expands in the downstream direction DK as depicted. This embodiment allows live insects to follow the discharge path PK out of the main discharge conduit 8K but to be deflected by the guiding channel 33K and follow a deflected discharge path PaK into the container 24K. The discharge guiding member 32K thus ensures that live insects are discharged into the container 24K by deflecting live insects from the main discharge conduit 8K into a deflected trajectory PaK toward the container 24K.
From
In an embodiment, the discharge guiding member 32K may further comprise a lower circumferential rim portion 35K, e.g. a circumferential flange portion, that engages the circumferential rim portion 24aK of the container 24K. The lower circumferential rim portion 35K can be used, for example, to cover a part of the container 24K when the guiding channel 33K is less wide than the container 24K, i.e. less wide that an upper opening of the container 24K.
As further depicted in
With reference to
Then, assuming the cyclone system 1K is in operation, the method continues with the step of c) collecting separated live insects being discharged from the discharge nozzle 6K. When a prescribed number of live insects have been collected, then the subsequent step of the method comprises the step of d) injecting air back into the discharge nozzle 6K with the air injection member 10K for a predetermined time period to temporarily stop discharge of live insects from the discharge nozzle 6K. In this step the injection member 10K is temporarily deployed to cease discharge of live insects by air suspension/cushioning through the injected air flow F1K, i.e. the first injected air flow F1K, or the first and a further injected air flow F2K, i.e. the second injected air flow F2K. Then during the predetermined time period when air injection is active, the method continues with the step of e) transferring the collected live insects away from the discharge nozzle 6K, which step may be associated with exchanging a loaded container 24K for an empty one.
In an embodiment, when the method step e) has been completed, then the method may further comprise the step off) repeating the steps c) to e), i.e. to c) collect separated live insects and when a desired number of live insects have been collected, to d) inject air back into the discharge nozzle 6K for a predetermined time period, and during this predetermined time period, to e) transfer the collected live insects away from the discharge nozzle 6K.
The present invention has been described above with reference to a number of exemplary embodiments as shown in the drawings. Modifications and alternative implementations of some parts or elements are possible, and are included in the scope of protection as defined in the appended claims.
Referring to
Now referring to
Now referring to
Now referring to
Now referring to
Now referring to
Now referring to
In contrast to the embodiment shown in
The convex side walls 113′, 113″ exhibit the advantageous effect in that when gas such as air flows over the convex side walls 113′, 113″ toward the top surface of the at least one gas guiding member 12′, 12″, 12′″, the speed of gas is maintained to a higher degree compared to gas flowing over flat side walls 113′, 113″ as shown in the embodiment of
For example, when a gas such as air is discharged from the second gas discharge members 131, 131′ at a speed of 4 m/sec over flat side walls 113′, 113″ as depicted in
In a further example, in case air is discharged from the second gas discharge members 131, 131′ at a speed of about 1.2 m/sec, then the air may approach the top surface of the gas guiding members at a speed of about 0.4 m/sec, which is sufficient to maintain suspension of live insects in the first laminar flow of gas, e.g. air, over the top surface of the at least one gas guiding member 12′, 12″, 12′″.
Therefore, gas flowing over the convex side walls 113′, 113″ maintains its speed to a much higher degree and a such less gas needs to be discharged by the second gas discharge members 131, 131′ for facilitating laminar flow over the top surface of the at least one gas guiding member 12′, 12″, 12′″ for transport of the live insects.
As the convex side walls 113′, 113″ allow for lower speeds of air being discharged from the second gas discharge members 131, 131′ with minimal loss of momentum, the discharged air has less impact on e.g. environmental conditions (e.g. temperature, humidity) surrounding the reservoirs comprising the live insects. For example, when a thermally insulated casing 5 is provided covering the gas guiding unit 112 and the feeder arrangement as mentioned above, then the convex side walls 113′, 113″ allow air to be discharged toward the top surface of the at least one gas guiding member 12′, 12″, 12′″ with reduced impact on environmental conditions on the inner side of the casing 5.
It is further noted that when a gas such as air flows over the convex side walls 113′, 113″, then the gas tends to closely follow and “stick” to the convex side walls 113′, 113″ in substantially laminar fashion so that turbulence is kept to a minimum. As a result, laminar flow over the convex side walls 113′, 113″ reduces the amount of conditioned air being disturbed or pulled away from the at least one reservoir 128, 128′ (see
In an embodiment, the convex side walls 113′, 113″ engage the top surface of the at least one gas guiding member 12′, 12″, 12′″ at an angle (β) between 45 and 60°, such that (laminar) air flowing over the convex side walls 113′, 113″ causes minimum disturbance of conditioned air around insect eggs contained in the at least one reservoir 128, 128′.
For example, relative humidity of air at 1 bar around the insect eggs or around live insects such as mites may be 80-85% at a temperature of 28° C. to 35° C.+/−0.5° C. The second gas discharge members 131, 131′ may then discharge a gas, e.g. air, at 1 bar at a temperature of 20° C. to 30° C. and with relative humidity of 40%-55%, e.g. 45%. As the discharged air flows in substantially laminar fashion over the convex side walls 113′, 113″ in a temperature controlled manner, condensation is prevented. Condensation of water vapor inside the casing 5 at any surface of the interior of the insects transport device is further prevented due to the provision of thermally insulated side walls and top wall of the casing. The inventors established that during operation of the insects transport device provided with air feed channel 5A, part of humid ‘climate’ air fed to the device by feed channel 5A, stays in the cabinet and part of the humid climate air is taken up by the laminar air flow. The volume of the humid climate air is about 20%-40% of the volume of the air building up the laminar air flow and therewith the climate air having a higher humidity than the ‘transport’ air in the laminar air flow, is sufficiently diluted in the less humid transport air, such that condensation of water vapor is prevented, for example inside the insects transport device and also when the transport air comprising a fraction of the climate air cools down to e.g. ambient temperature of 18° C.-23° C. upon exiting the insects transport device, and entering tubing, etc.
In the embodiment shown, the insects transport device 100 may be considered to be the same as the one shown in
The cover member 132 prevents that the first laminar flow over the gas guiding unit 112, i.e. the at least one gas guiding member 12′, 12″, 12′″, drags too much conditioned air toward the exit of the insects transport device 100 at a proximal end thereof. In case too much air is being dragged along with the first laminar flow, then this would produce too much turbulence at the exit because of the limited flow capacity there through causing air being lifted upward at the proximal end of the live insect larvae transport device 100.
Therefore, the cover member 132 maintains homogenous distribution of conditioned air around the insect eggs or live mites in the at least one reservoir 128, 128′, 128a, 128a′ by minimizing the amount of conditioned air being dragged away and/or downward therefrom along with the first laminar flow over the gas guiding unit 112.
In an embodiment, the cover member 132 has a height such that it extends and remains underneath the at least one reservoir 128, 128′, 128a, 128a′ so that conditioned air around the insect eggs or around the mites is prevented from being dragged with the first laminar flow over the gas guiding unit 112.
In another embodiment, the cover member 132 may further comprise a sloped roof 133 to prevent that live insects collect on the cover member 132 when dropping from the at least one reservoir 128, 128′, 128a, 128a′ onto the cover member 132, thereby ensuring that the live insects reach the first laminar flow of gas over the gas guiding unit 112.
In a further embodiment, the cover member 132 comprises a plurality of cover side walls 134, e.g. oppositely arranged cover side walls 134, wherein each cover side wall 134 extends in upward and longitudinal/lengthwise direction along one of the convex side walls 113′, 113″ to further reduce any suction or dragging of conditioned air by the first laminar air flowing over the gas guiding unit 112. Note that lowest edges of each cover side wall 134 are arranged above the gas guiding member 112 at the aforementioned clearance distance C. In a further embodiment, the cover member 132 comprises a bottom side (not visible in
In an exemplary embodiment, the cover member 132 has a width wc which may be substantially the same as a width Wg of the gas guiding unit 112. Since the cover member 132 is arranged above the gas guiding unit 112 at the clearance distance C, a slit “S” is provided between the cover member 132 and each of the convex side walls 113′, 113″. These slits S still allow discharged air from the second gas discharge members 131, 131′ to flow in laminar fashion over the convex side walls 113′, 113″ and pass through these slits S toward each of the at least one gas guiding members 12′, 12″, 12′″.
In an exemplary embodiment, the cover member 132 may have a height between 10 cm to 20 cm, e.g. 20 cm, and a width Wc of 3 cm to 7 cm, e.g. 5 cm.
As mentioned earlier, the at least one reservoir 128, 128′, 128a, 128a′ comprising live insects, e.g. insect eggs or mites, are to be maintained at a controlled and predetermined temperature and relative air humidity to stimulate and facilitate optimal hatching or optimal disposal of mites through the through holes in the bottom floor of the mite cage 128a, 128a′, such that optimal release of live insects from the at least one reservoir 128, 128′, 128a, 128a′ into the live insect receiving portion is achieved.
To provide optimal temperature and relative humidity condition,
In an embodiment, the casing 5 may be provided with a secondary top wall 2a arranged below the top wall 2 at wall distance Dw therefrom such that a cavity space 135 is defined between the top wall 2 and secondary top wall 2a. The secondary top wall 2a further comprises one or more slits 136 such that air from the air feed conduit 5a entering the cavity/buffer space 135 is able to flow toward the inner volume V. That is, the one or more slits 136 fluidly connect the cavity/buffer space 135 and the inner volume V of the casing 5. The one or more slits 136 provided in the secondary top wall 2a allow air, e.g. temperature and/or humidity controlled air, to be provided to the inner volume V in distributed fashion so as to minimize turbulence in the inner volume. Therefore, the cavity space 135 in conjunction with the one or more slits 136 allow air from the air feed conduit 5a to enter the inner volume V with maximum homogeneity. The casing 5 is provided with thermally insulating top wall and side walls.
In an embodiment, the one or more slits 136 are arranged in longitudinal fashion, i.e. in a lengthwise direction “L” as depicted, thereby providing conditioned air in homogenous fashion along the gas guiding unit 112. In an exemplary embodiment, each of the one or more slits 136 extends along 70% to 90%, e.g. 80%, of a length of the first laminar flow of gas, e.g. air, over the top surface of the at least one gas guiding member 12′, 12″, 12′″. In an exemplary embodiment, each of the one more slits 136 has a length between 50 cm to 100 cm, e.g. 60 cm, 65 cm, 70 cm. In a further exemplary embodiment, each of the one or more slits 136 has a width of about 3 cm to 6 cm, e.g. 4 cm or 5 cm, to further facilitate homogenous distribution of conditioned air entering the inner volume V of the thermally insulated casing 5.
In an advantageous embodiment, the one or more slits 136 extend above the at least one reservoir 128, 128′, 128a, 128a′ containing the live insects, e.g. insect eggs or live mites, for which conditioned air is to be provided for optimized hatching, or optimized migration downward in the mite cage 128a, 128a′.
In another embodiment, each of the one or more slits 136 comprises a plurality of perforations covering 40% to 60%, e.g. 50%, of a surface area of the slit 136. In further embodiments each of the perforations is a substantially circular perforation having a diameter of about 4, 5, or 6 mm for example.
In an embodiment, the secondary top wall 2a with the one or more slits 136 is arranged above the at least one reservoir 128, 128′ at a height of 5 cm to 15 cm, e.g. 10 cm to provide the conditioned air to the at least one reservoir 128. 128′.
As mentioned earlier, the insects transport device 100 may comprise a live insects counting device 8, e.g. a camera, for counting live insects in the first laminar flow exiting the insects transport device 100 at the proximal end of the live insect discharge member 11 as shown in
To further improve upon the accuracy and reliability of counting live insects exiting the insects transport device 100, further embodiments of the live insects discharge member 11 as discussed earlier are conceivable. For example,
In the depicted embodiments, the live insect discharge member 11 may comprise a throat portion 137 arranged between the distal end 10′, i.e. the first end, and a proximal end 10″, i.e. the second end, of the live insect discharge member 11. That it, a discharge channel 139 of the live insect discharge member 11 extends between the distal end 10′ and proximal end 10″ thereof and comprises a constricted or choked channel portion 140 at the throat portion 137. Here, the distal/first end 10′ is configured for connection to the insects transport device 100 such that live insects exiting the insects transport device 100 can travel through the discharge channel 139 by entering at the distal/first end 10′ and exiting from the proximal/second end 10″.
As shown, the throat portion 137 is provided with a through hole 138, e.g. shaped as a (elongated) slit 138, laterally/sideways extending through the throat portion 137. The through hole/slit 138 allows the counting device 3, e.g. a camera, to be arranged next to the slit shaped through hole 138 and have a field of view into the discharge channel 139, in particular the constricted channel portion 140, for counting the number of live insects passing through the live insect discharge member 11 as they exit the insects transport device 100.
The advantage of having the slit shaped through hole 138 at the constricted channel portion 140 is that a pressure drop in the constricted channel portion 140 will develop according to the Venturi effect or Venturi principle. That is, the constricted channel portion 140 induces a Venturi effect allowing outside air “A” to be drawn/sucked into the constricted channel portion 140 via the slit shaped through hole 138 when an air stream carrying live insects flows through the discharge channel 139. As a result, suction at the slit shaped through hole 138 allows live insects to be counted by the counting device 3 whilst preventing that live insects escape the live insect discharge member 11 via the slit shaped through hole 138.
For improved operation of the counting device 8, e.g. a camera, a light source such as a lamp 9 may be provided as mentioned earlier with reference to
Note that suction at the slit shaped through hole 138 allows the counting device 3 to be arranged on both sides S1, S2, e.g. above or below, the live insect discharge channel 11 and the light source 9 may then be arranged below or above the live insect discharge channel 11 respectively. In any case, the constricted channel portion 140 prevents live insects escaping via the slit shaped through hole 138 on both sides S1, S2 of the live insect discharge member 11. Since live insects cannot escape through the slit shaped through hole 138, contamination of the counting device 8 and/or light source 9 is eliminated, allowing the counting device 8 and light source 9 to be placed on either side S1, S2 of the live insect discharge member 11 whilst still allowing accurate counting of the number of live insects exiting the insects transport device 100.
As shown in
To obtain a most optimal field of view into the constricted channel portion 140, an embodiment is provided wherein the slit shaped through hole 138 has a length of at least 90% percent of a width of the constricted channel portion 140 in the lateral direction of the slit shaped through hole 138. This embodiment minimizes the number of live insects that could potentially bypass the field of view of the counting device 8.
In an embodiment, the slit shaped through hole 138 comprises a chamfered or rounded downstream inner edge 141, i.e. extending in the lengthwise direction of the slit shaped through hole 138 on a downstream side thereof, thereby reducing turbulence and maintaining laminar flow within the constricted channel portion 140 when air A is being drawn into the constricted channel portion 140 in the direction of air flowing from the first end 10′ to the second end 10″.
The live insect discharge member 11 with the slit shaped through hole 138 enabling a field of view into the constricted channel portion 140 allows for an extremely useful counting device 8 which is able to accurately count the number of live insects exiting the insects transport device 100.
In particular, because accurate counting of live insects is now possible by means of the live insect discharge member 11, information on hatch and development characteristics of live insects in the insects transport device 100 can be deduced. For example, by counting the number live insects passing the live insect discharge member 11 it is possible to deduce what the effects are of temperature and /or relative humidity on live insects (e.g. insect eggs, mature mites) and their hatch time (e.g. when eggs of for example black soldier flies are present in ovisites 128, 128′) or their migration time (e.g. when mites are present in the reservoir(s) 128a, 128a′) in the at least one reservoir 128, 128a. Therefore, the live insect discharge member 11 and counting device 8 allow for gaining further information on live insect hatching characteristics or live insect migration characteristics.
Although the constricted channel portion 140 prevents live insect escaping though the slit shaped through bore 138, an outgoing air stream Ao with live insects exiting the live insect discharge member 11 at its proximal/second end 10″ is generally slower than an incoming air stream Ai entering the distal/first end 10′. To compensate for this loss of speed, an embodiment is provided wherein the proximal/second end 10″ of the live insect discharge member 11 is provided with an air amplifier unit 5aK which is configured to inject further air Af into the second end 10″ of the live insect discharge member 11. This ensures that an outgoing air stream Ao with live insects has sufficient speed and momentum to flow to other parts of the insects transport device, such as a cyclone separation system 1K, connected to the second end 10″ of the live insect discharge member 11.
In an exemplary embodiment, the air amplifier unit 5aK comprises a circumferential chamber 143 fluidly coupled to an air feed connection 144 for connection to an air feed allowing further air Af to be injected into the proximal second end 10″ of the live insect discharge member 11, and wherein one or more air amplifier outlets 145 are circumferentially arranged in an inner wall 147 of the second end 10″ of the live insect discharge member 11 and wherein the one or more air amplifier outlets 145 are fluidly connected to the circumferential chamber 143. In this embodiment, the one or more air amplifier outlets 145 allow for an even injection of the further air Af into the second end 10″ such that turbulence is minimised. In an exemplary embodiment, a single air amplifier outlet 145 may be provided in the form of a circumferential slit in the inner wall 147 fluidly coupled to the circumferential chamber 143, allowing for even injecting of further Af.
As mentioned above, the air amplifier unit 5aK allows for an outgoing air stream Ao with live insects which has sufficient speed and momentum to flow to other parts of a system, such as a cyclone separator 1K, connected to the second end 10″ of the live insect discharge member 11.
As depicted, a cyclone separation system 1K is connected to one or more insects transport devices 100 to separate live insects from an outgoing air stream Ao of each live insect discharge member 11. The cyclone separation system 1K comprises a main cyclone chamber 2K having a top chamber part 3K and a conical shaped bottom chamber part 4K, wherein the top chamber part 3K is connected to one or more intake channels 5K each of which is arranged for connection to a primary air source providing an air stream comprising live insects. Here, the air stream provided by the primary air source is an outgoing air stream Ao of a live insect discharge member 11 as described above. Therefore, each of the one or more intake channels 5K is arranged for connection to an insects transport device 100 of the one or more insects larvae transport devices 100.
Note that only one insects larvae transport device 100 is depicted for clarity purposes and the skilled person will understand the each of the depicted first ends 10′ of the live insect discharge members 11 is connected to an insects transport device 100.
The bottom chamber part 4K of the cyclone separation system 1K is connected to a discharge nozzle 6K comprising a discharge end having a main discharge conduit (not shown) for discharging the live insects from the cyclone separation system 1K. The discharge end comprises an air injection member 7K for connection to a secondary air source 10K and wherein the air injection member 7K is configured to inject air back into the discharge nozzle 6K. Injecting air back into the discharge nozzle 6K stops the discharge of live insects.
In an advantageous embodiment, the air injection member 7K is configured for intermittent air injection back into the discharge nozzle 6K.
Each of the one or more insects transport devices 100 provides an outgoing air stream Ao with live insects passing through a live insect discharge member 11 toward the cyclone separation system 1K, which subsequently discharges separated live insects in batch wise fashion by intermitted operation of the air injection member 7K. When desired, the cyclone separation system 1K, discharges separated live insects in continuous fashion by continuous operation of the air injection member 7K.
As the skilled person will understand, in operation the one or more intake channels 5K carrying the outgoing air streams Ao induce a main vortex in the top chamber part 3K allowing centrifugal separation of the live insects from the combined outgoing air streams Ao in the top chamber part 3K. The separated live insects follow a conical inner wall of the bottom chamber part 4K toward the discharge nozzle 6K. Due to the conical shaped bottom chamber part 4K, an ascending inner vortex of “clean” air is generated that exits the top chamber part 3K through an air exit 9K arrange thereon.
Discharged live insects may be collected in a container 24K arranged underneath the discharge nozzle 6K and wherein the container 24K is movable by means of a conveyor system 25K. For example, such container is a crate provided with feed substrate for live insects such as insect larvae, such as for example neonate larvae of black soldier fly. For example, in case the container 24K contains a desired number of live insects, then the air injection member 7K may be activated to inject air back into the discharge nozzle 6K as a result of which discharge of live insects is temporarily stopped. As the discharge of live insects has stopped, the container 24K may be replaced with another container, and once the other container has been correctly positioned, the air injection member 7K may be deactivated to resume discharge of separated live insects from the cyclone separation system 1K. This way, accurate, controllable and constant dosing of for example live adult insects such as live mites is made possible.
In an embodiment, the cyclone separation system 1K may comprise a further counting device 23K, e.g. a further camera, arranged next to the discharge nozzle 6K for counting the number of live insects being discharged therefrom. Activation and deactivation of the air injection member 7K may be controlled based on the counted number of live insects being discharged. Optionally, a further light source 28K may be provided to improve illumination conditions for the further counting device 23K.
As further shown, the second end 10″ of each live insect discharge member 11 may be provided with an air amplifier unit 5aK to boost the outgoing air stream Ao such that it attains sufficient speed and momentum.
Advantageously, a plurality of insects transport devices 100 are connected to a corresponding number of intake channels 5K so that the cyclone separation system 1K may operate continuously without interruption to the flow of live insects entering the cyclone separation system 1K. In this way the cyclone separation system 1K can be scaled up to achieve batch wise discharge of any desired number of live insects. Note that the top chamber part 3K may be connected to an auxiliary intake channel 11K configured to provide a “pilot” air stream into the top chamber part 3K to further optimize centrifugal separation of the live insects entering the main cyclone body 2K.
These embodiments of insects transport devices of the invention are all suitable for transportation of live neonate larvae of the black soldier fly, which larvae have a body diameter of between 1 mm and 4 mm and a body length which ranges between 5 mm and 12 mm. In addition, these embodiments of insects transport devices of the invention are all suitable for transportation of live insects such as mites.
While the invention has been described in terms of several embodiments, it is contemplated that alternatives, modifications, permutations and equivalents thereof will become apparent to one having ordinary skill in the art upon reading the specification and upon study of the drawings. The invention is not limited in any way to the illustrated embodiments. Changes can be made without departing from the scope which is defined by the appended claims.
Turning to
In view of the above, an embodiment may thus be provided wherein the cyclone separation system 1K comprises an air exit 9K arranged on the top chamber part 3K and wherein the air exit 9K comprises pivotally arranged slats 311, e.g. openable slats 311 with pivots 312, thereby allowing adjustment of air pressure inside the cyclone separation system 1K. In an even further embodiment, the air exit 9K may comprise a slat operation driver/control unit 313 for moving the slats 311 between an open state and a closed state.
The live insects device of the invention provides for efficient and accurate and constant dosing of live insects such as insect eggs, embryo, neonate larvae, larvae, prepupae, pupae, imago, adult insect, for example fly neonate larvae such as black soldier fly larvae 1 second-1 day of age, preferably 10 seconds-2 hours of age, or for example imago such as mites. For applying the insects transport device 1, 100 for counting, dosing such as batch wise dosing, of e.g. imago such as mites, a reservoir 128a adapted to the delivery of such mites to the laminar air flow, is provided.
Similar to the cyclone separation system 1K of the embodiment displayed in
The embodiment displayed in
An embodiment is the cyclone separation system 1K of the invention, wherein at least one of the one or more intake channels 5K which is connected to the top chamber part 3K is further connected to the primary air source providing the air stream AK comprising live insects,
wherein the primary air source is an insects transport device(s) 1, 100, and wherein the at least one intake channel 5K is in fluid connection with a live insect discharge member (11 of the insects transport device 1, 100,
wherein the insects transport device 1, 100 comprises:
a gas guiding unit 12, 112, 112′ comprising a distal end 15 and a proximal end 121″, and at least one longitudinal gas guiding member 12′, 12″ comprising a distal end and a proximal end, wherein the distal end of the gas guiding member is arranged at the distal end of the gas guiding unit and wherein the proximal end of the gas guiding member is directed toward the proximal end of the gas guiding unit, further comprising a live insect discharge member 11 comprising a flat surface with a first end and a second end, the discharge member coupled with its first end to the proximal end of the gas guiding unit 12,
wherein the at least one gas guiding member further comprises a smooth top surface extending from the distal end to the proximal end of the gas guiding member, the top surface comprising a live insect receiving portion between the distal end and proximal end of the at least one gas guiding member;
a first gas discharge member located at the distal end of the gas guiding unit and being configured to connect to a first source of gas 200, wherein the first gas discharge member is further configured to provide a first laminar flow of gas over the top surface of the at least one gas guiding member from the distal end to the proximal end thereof during operation of the insects transport device, wherein the first gas discharge member is in fluid connection with a sensor for sensing the temperature and/or the humidity of the gas provided by the first source of gas; and wherein the insects transport device further comprises
a feeder arrangement 127 located above the live insect receiving portion of the top surface of the gas guiding unit, wherein the feeder arrangement is configured to receive at least one reservoir 128 for live insects such as live insects and live insect larvae at a predetermined distance above said live insects receiving portion of the top surface of the at least one gas guiding member for releasing live insect larvae or live insects above the live insect receiving portion, wherein the feeder arrangement 127 is configured to receive at least one reservoir 128, 128′, 128a, 128a′ for releasing live insects by gravity-driven free fall through gas medium present in the insects transport device, above the live insects receiving portion, and therewith in the first laminar flow of gas, such that during operation of the insects transport device insects freely flow from the reservoir to and into and with the first laminar flow of gas without contacting a surface of the gas guiding member(s),
wherein the insects transport device 1, 100 further comprises a casing 5, 105 covering the gas guiding unit 12, 112, 112′ and the feeder arrangement 127 wherein said casing 5, 105 comprises a thermally insulated top wall 2 and thermally insulated side walls 3, 4, 4A, 7 defining a closed inner volume V in which the at least one reservoir 128, 128′, 128a, 128a′ is arranged, and wherein the insects transport device 1, 100 comprises an air feed channel 5a comprising tube 401 and connector 403 connected to the top wall 2 through opening 402, optionally further comprising gas temperature controller and absolute air humidity control unit 404, configured to provide air of a controllable and desired temperature and/or controllable and desired relative humidity to the inner volume V of the casing 5, 105, and
wherein the live insects receiving portion further comprises convex side walls 113′, 113″ located along longitudinal sides of the at least one longitudinal gas guiding member 12′, 12″, 12′″, wherein each convex side wall 113′, 113″ has a top side and a bottom side and a smooth convex surface 115 arranged between the top and bottom side, the bottom side being connected to a longitudinal side of the at least one gas guiding member 12′, 12″, 12′″, and
wherein the top side of each convex side wall 113′, 113″ is provided with a second gas discharge member 131, 131′ comprising a connector configured to connect the second gas discharge member 131, 131′ to a source of gas, preferably the first source of gas, for providing a second laminar flow of gas over the surface 115 of the convex side wall 113′, 113″ from the top side thereof to the at least one gas guiding member 12′, 12″, 12′″ during operation of the insects transport device 100, wherein the second gas discharge member 131, 131′ is in fluid connection with a sensor for sensing the temperature and/or the humidity of the gas provided by the source of gas,
the insects transport device further comprising a cover member 132 extending along and above the at least one gas guiding member 12′, 12″, 12′″ at a clearance distance C with respect thereto.
An embodiment is the cyclone separation system 1K of the invention, wherein the first gas discharge member comprised by the insects transport device 1, 100 is further configured to provide a continuously flowing first laminar flow of gas over the top surface of the at least one gas guiding member from the distal end to the proximal end thereof during operation of the transport device.
An embodiment is the cyclone separation system 1K of the invention, wherein the casing 5, 105 of the insects transport device 1, 100 is a gas-tight casing, preferably an air-tight casing.
An embodiment is the cyclone separation system 1K of the invention, wherein the insects transport device comprises at least two imbricatedly coupled longitudinal gas guiding members 12′, 12″, the gas guiding members being imbricatedly coupled with a coupler 18, 18′ located at the proximal end 21′, 121′ of a first gas guiding member and the distal end 22′, 122′ of a second gas guiding member.
An embodiment is the cyclone separation system 1K of the invention, wherein the coupler of the insects transport device which imbricatedly couples the at least two gas guiding members is provided with a further gas discharge member 20, 114′ comprising a connector configured to connect each further gas discharge member to a source of gas, preferably the first source of gas, and wherein the further gas discharge member(s) is/are configured to reinforce from below the first laminar flow of gas over the top surface of the at least one gas guiding member from the distal end to the proximal end of the gas guiding unit during operation of the insects transport device.
An embodiment is the cyclone separation system 1K of the invention, wherein the gas is air, preferably temperature-controlled air and/or wherein the air is a relative humidity-controlled air.
An embodiment is the cyclone separation system 1K of the invention, wherein the first source of gas comprises a fan for driving gas through the gas discharge member(s) of the insects transport device.
An embodiment is the cyclone separation system 1K of the invention, wherein the live insect discharge member 11 of the insects transport device comprises a live insects counting device 8, preferably a high-speed camera 8, for counting live insects in the first laminar flow exiting the insects transport device at the proximal end of the live insect discharge member.
An embodiment is the cyclone separation system 1K of the invention, wherein the reservoir 128 for live insects of the insects transport device is an insect egg collection interface or an insect egg holder or wherein the reservoir 128a for live insects is a live insect cage provided with a perforated bottom floor such as a mesh, sieve, plate with through holes.
An embodiment is the cyclone separation system 1K of the invention, wherein the insects transport device is arranged to transport live black soldier fly neonate larvae, for example within 2 seconds-5 minutes post-hatching, or is arranged to transport live mites.
An embodiment is the cyclone separation system 1K of the invention, wherein the cover member 132 of the insects transport device comprises a plurality of cover side walls 134, wherein each cover side wall 134 extends in upward and longitudinal/lengthwise direction along one of the convex side walls 113′, 113″.
An embodiment is the cyclone separation system 1K of the invention, wherein the cover member 132 of the insects transport device further comprises a sloped roof 133.
An embodiment is the cyclone separation system 1K of the invention, wherein the casing 5, 105 of the insects transport device further comprises a secondary top wall 2a arranged below the top wall 2 at a wall distance Dw therefrom defining a cavity space 135 between the top wall 2 and the secondary top wall 2a, wherein the secondary top wall 2a further comprises one or more slits 136 fluidly connecting the cavity space 135 and the inner volume V of the casing 5.
An embodiment is the cyclone separation system 1K of the invention, wherein the inner side of top wall 2 or, if present, the inner side of secondary top wall 2a of the insects transport device is provided with a light source 405 and/or a heater 405 positioned above the feeder arrangement 127, such that reservoirs 128a, 128′ positioned in the feeder arrangement 127 are irradiable with light by the light source 405 from above the reservoirs and/or heatable with the heater 405 from above the reservoirs 128a, 128a′ during operation of the insects transport device 1, 100.
An embodiment is the cyclone separation system 1K of the invention, wherein the live insect discharge member 11 of the insects transport device comprises a throat portion 137 arranged between the first end 10′ and the second end 10″ of the live insect discharge member 11, wherein a discharge channel 139 extends between the first end 10′ and the second end 10″ and comprises a constricted channel portion 140 at the throat portion 137, wherein the constricted channel portion 140 preferably comprises a rectangular cross section and wherein the throat portion 137 is optionally provided with a slit shaped through hole 138 laterally extending through the throat portion 137, wherein the slit shaped through hole 138 preferably has a length of at least 90% percent of a width of the constricted channel portion 140 in a direction of the slit shaped through hole 138 and/or wherein the slit shaped through hole 138 optionally comprises a chamfered or rounded downstream inner edge 141.
An embodiment is the cyclone separation system 1K of the invention, wherein the second end 10″ of the live insect discharge member 11, 11a of the insects transport device is provided with an air amplifier unit 5aK, 142′ which is configured to inject further air Af, 701 into the second end 10″, or wherein the second end 10″ of the live insect discharge member 11, 11a of the insects transport device is provided with a tube 11b connected at the proximal end of the tube 11b to the second end 10″ of the live insect discharge member 11, 11a and connected at the distal end of the tube 11b to an air amplifier unit 5aK, 142′ which is configured to inject further air Af, 701 into the distal end of the tube 11b, wherein the air amplifier unit is optionally provided with a sensor for sensing the temperature and/or the humidity of the gas provided by a source of gas, preferably a second source of gas, for providing the further air Af, 701.
An embodiment is the cyclone separation system 1K of the invention, wherein the system is encompassed by an air-conditioned volume 900 such as a climate room 900, and wherein preferably both temperature and air humidity are controlled in said air-conditioned volume 900, wherein temperature controlled air is kept at a temperature of between 25° C. and 36° C., such as 26° C.-35° C. or 27° C.-34° C. and/or wherein specific-humidity controlled air with a specific humidity at 1 atm. Is kept at between 0.014 kg/kg and 0.026 kg/kg, preferably 0.015 kg/kg-0.025 kg/kg, more preferably 0.016 kg/kg-0.024 kg/kg inside the air-conditioned volume.
An aspect of the invention relates to a method for transporting live insects such as live neonate insect larvae or live mites comprising the steps of:
An aspect of the invention relates to the use of the cyclone separation system 1K of the invention for dosing live insects such as neonate insect larvae or live mites, wherein live neonate insect larvae or live mites transported by said insects transport device are collected at the discharge end 7K of the discharge nozzle 6K of the cyclone separation system 1K, in a first receptacle for a period of time until a predetermined number of live neonate insect larvae or live mites passed said the proximal end of the gas guiding unit of the insects transport device or the second end of the insect discharge member of the insects transport device or said discharge end 7K of the discharge nozzle, such that a dose of live neonate insect larvae or a dose of live mites is provided.
An embodiment is the use according to the invention, wherein the predetermined number of live neonate insect larvae or live mites is established by a counting device for counting live insects in the first laminar flow exiting the insects transport device, and/or by a counting device for counting live insects exiting the cyclone separation system 1K through the discharge end 7K of the discharge nozzle 6K.
An embodiment is the method according to the invention or use according to the invention, wherein the air in the first laminar flow and/or in the second laminar flow and/or the further air Af, 701 is temperature controlled air at a temperature of between 21° C. and 37° C., such as 23° C.-35° C. or 23,5° C.-34° C.
An embodiment is the method according to the invention or use according to the invention, wherein the air in the first laminar flow and/or in the second laminar flow and/or the further air Af, 701 is specific-humidity controlled air with a specific humidity at 1 atm. of between 0.012 kg/kg and 0.026 kg/kg, preferably 0.013 kg/kg-0.025 kg/kg, more preferably 0.014 kg/kg-0.024 kg/kg.
An embodiment is the method according to the invention or use according to the invention, wherein the air provided by the air feed channel 5a of the insects transport device is temperature controlled air at a temperature of between 25° C. and 36° C., such as 26° C.-35° C. or 27° C.-34° C. and/or is specific-humidity controlled air with a specific humidity at 1 atm. of between 0.014 kg/kg and 0.026 kg/kg, preferably 0.015 kg/kg-0.025 kg/kg, more preferably 0.016 kg/kg-0.024 kg/kg.
An aspect of the invention relates to a single dose of insects obtained with or obtainable with the method of the invention.
An embodiment is the single dose of insects according to the invention, wherein the insects are living black soldier fly neonate larvae, preferably with any larvae-to-larvae age difference post-hatching of less than 2 hours, when the individual insects in the single dose are considered, such as between 2 seconds and 30 minutes or 3 seconds-1 minute.
Number | Date | Country | Kind |
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2022057 | Nov 2018 | NL | national |
PCT/NL2018/050867 | Dec 2018 | NL | national |
2023315 | Jun 2019 | NL | national |
Filing Document | Filing Date | Country | Kind |
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PCT/NL2019/050767 | 11/21/2019 | WO | 00 |
Number | Date | Country | |
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62857842 | Jun 2019 | US |