BE1026942B1 - MODIFIED REFRIGERATION CONTAINER FOR REFRIGERATED TRANSPORT VIA MOTORIZED TRANSPORT INCLUDING A DRONE AND / OR A MOTORCYCLE - Google Patents

Abstract

A thermoelectric cooling box suitable for mounting on a motorcycle and / or drone, comprising an essentially beam or cube-shaped cavity, surrounded by a top wall, a bottom wall and four side walls, whereby the cavity of the cooling box is cooled, further comprising the cooling box, the following elements: a. at least one temperature sensor suitable for registering the temperature in the cavity of the cooling box; b. at least one cooling device for actuating a thermoelectric effect suitable for cooling the cavity of the cooling box, the cooling being controlled on the basis of the recorded temperature in the cavity of the cooling box, preferably wherein the cooling box has at least two, further preferably comprises at least three cooling devices; c. at least one battery for supplying energy to the at least one cooling device, the battery comprising an electrical connector suitable for coupling the battery to a battery of the motorcycle and / or drone; d. preferably at least one grid positioned on at least one outer surface of the cooling box, suitable for dissipating the heat generated by the at least one cooling device. wherein all walls of the refrigeration box include an outer layer, an intermediate layer and an inner layer.

Description

| BE2019 / 5832

MODIFIED REFRIGERATION CONTAINER FOR REFRIGERATED TRANSPORT VIA MOTORIZED TRANSPORT INCLUDING A DRONE AND / OR A MOTORCYCLE

TECHNICAL FIELD The invention relates to an improved thermoelectric cooling box suitable for mounting under a drone and / or on a motorcycle. More specifically, the invention is in the technical field of transport containers and autonomous mobile devices. The invention also relates in a second aspect to a method for controlling the temperature of a thermoelectric cooling box suitable for use on a drone and / or motorcycle. to be mounted.

STATE OF THE ART BRMU9102586 describes a cooling box the structure of which consists of a thermally insulating material suitable for the thermal insulation of the inside of the cooling box, Furthermore, the cooling box comprises Peltier elements for cooling and / or heating the cooling box, an electronic circuit, ventilation grilles, a system for selecting the temperature in the cooling box and an on / off button. BRMUS102586 further describes that the cooling box can be heated or cooled by conduction, convection, radiation or a combination thereof, using a heat-conducting metal plate or a forced ventilation system. The document then describes that the Pellierelermenten are connected to the electrical system of the motorcycle, and thus supplied with power. In an alternative form, a battery can be attached to the system. U520180180343 describes thermo-electrically powered, insulated refrigeration equipment that can be mounted on a motorcycle to keep food and drink items cool while riding, whereby the killer equipment can be electrically connected to the motorcycle for power.

© BE2019 / 5832 The document further describes that the thermoelectric system of the refrigerator box comprises a “cool” side and an opposite “hot” side. The “cool” side is coupled to a lower surface of a liner heatsink. The thermoelectric system is configured to be electrically connected to the motorcycle battery such that the thermoelectric system conducts the heatsink and the liner through conduction. JP2002225763 describes a motorcycle that can supply an alternating current of 100 V, using the driving force of the motor, to a cooling box on the motorcycle, the cooling box comprising a cooling function that uses the generated alternating current. KR 2011/0028037 and KR 2017/0028657 describe a cooling box for transport on a motorcycle.

The applicant notes that the listed devices are not suitable for protecting and / or stabilizing the contents of the refrigeration box. Especially in the event that the cooling box falls and / or in the event that the motorcycle / drone is involved in an accident. It is further noted that the cooling method is not used in an efficient manner in the described cooling boxes. Moreover, the applicant finds that transporting a cargo according to the described devices leads to transporting the cargo without being able to control the temperature during a journey. Strict temperature control is especially important in transportation for the medical, pharmaceutical and biotechnology sectors. Furthermore, the applicant notes that opening the described cooling boxes leads to an excessive loss of cold air, whereby the efficiency of the cooling decreases.

The present invention aims to solve at least some of the above-mentioned problems or drawbacks.

SUMMARY OF THE INVENTION In a first aspect, the present invention relates to an improved thermoelectric cooling box suitable for mounting under a drone and / or on a motorcycle.

© BE2019 / 5832, according to claim 1, In a second aspect, the invention relates to a method for controlling the temperature of a thermoelectric cooling box suitable for mounting under a drone and / or on a motorcycle, according to the claim which pertains to this.

Compared to known devices, the invention comprises a more user-friendly, more efficient, better quality and safer way of transporting a load. Today, goods must be transported faster, more efficiently and with a higher quality. Especially in the medical, pharmaceutical and biotechnology sectors, the speed and quality of the transport can be crucial. In particular, blood, organs, tissues and / or medical samples sometimes have to be very be transported quickly under the right conditions. If the transport is not done under the right conditions, this will have consequences for the cargo. For example, blood can be destroyed because of the incorrect temperature during transport. This leads to great wastage of valuable and / or life-saving resources. For example, if an erythrocyte concentrate is transported at a temperature higher than 7 ° C for a longer period, it will no longer be used. The problem is that there is a general shortage of erythrocyte concentrates, so that any waste must be avoided. The problem mentioned is not limited to erythrocyte concentrates, but also to all kinds of other donor samples, such as bone marrow, organs or tissues. In the first instance, the invention makes it possible to simultaneously cool and transport loads with a drone and / or motorcycle. Motorcycles and drones can easily maneuver between the existing heavy traffic, increasing the efficiency of the transport. Furthermore, the parking pressure can be avoided with the motorcycle and / or drone. Subsequently, the invention allows Loe to cool the cooling box in a controlled manner, Due to the presence of one or more cooling devices, which cool on the basis of a thermoelectric effect, and a temperature sensor, it is possible to closely monitor the temperature of the cooling box. and to adjust the temperature with great accuracy. The one or more cosl elements in combination with a battery, which can be connected to a battery of the drone or motorcycle and provides energy to the one or more cooling devices, ensure an even more efficient cooled transport. Because the battery includes an electrical connector and is continuously charged during transport with the drone or motorcycle, the cooling box can easily be removed from the drone or motorcycle, while the battery remains autonomous in the cooling box

© BE2019 / 5832 cooling, In this way it is ensured that the contents of the cooling box are cooled DIFF as far as its effective final destination. The combination of the aforementioned elements ensures a controlled, efficient and user-friendly refrigerated transport, whereby a refrigeration temperature of below 0 ° C can be reached.In addition, the walls of the refrigeration box fall over a three-layer composition, with an insulating material positioned between two hard layers. is. The composition of the walls makes it possible to obtain a thermally insulated hard cooling box. Due to the stated choice of materials, the thickness of the walls and the weight of the cooling box can be reduced. As a result, a cooling box is obtained, in which the contents can be protected against heavy impact and in which the ratio between the thickness of the walls of the kosi box and the volume of the volume of the cooling box is optimized. The applicant notes that the cooling box could protect the contents when it dropped the cooling box from 4 meters. Furthermore, the applicant notes that the cooling box moreover had a better thermal insulation quality compared to the classically used cooling boxes. In a specific embodiment, the cooling box is moreover provided with a vibration reduction system and / or one or more gyroscopes, in order to reduce as much as possible vibrations on the charge in the cooling box.

Further advantages, features and examples of the present invention are described in the detailed description.

DESCRIPTION OF THE FIGURES Figure 1 shows a perspective view of a cooling box according to the invention from the outside. Figure 2 shows a perspective view of a cooling box according to the invention from the inside, Figure 3 shows a perspective view of a cooling box according to the invention from the outside. Figure 4 shows a perspective view of a cooling box according to the invention from the outside.

BE2019 / 5832 Figure 5 pays off for a perspective view of a cooling box according to the invention from the inside.

DETAILED DESCRIPTION Unless otherwise defined, all terms used in the description of the invention, including technical and scientific terms, have the meaning as commonly understood by those skilled in the art of the invention. For a better assessment of the description of the invention. the invention, the following terms are explicitly explained.

“A”, “the” and “it” throughout this document refer to both singular and plural unless the context clearly suggests otherwise. For example, "a segment" means one or more than one segment.

When “about” or “around” is used in this document for a measurable quantity, parameter, time duration or moment, and the like, it means variations of +/- 20% or less, preferably +/- 10% or less, more preferably +/- 5% or less, even more preferably +/- 1% or less, and even more preferably +/- 0.1% or less than and of the quoted value, insofar as such variations of are applicable in the described invention. However, this should be understood to mean that the value of the quantity using the term “approximately” or “round” is itself specifically disclosed.

The terms “comprise”, “comprising”, “consisting of”, “consisting of”, “incorporating”, “containing”, “containing”, “containing”, “containing” are synonyms and are inclusive or open terms that denote the indicate the presence of what follows, and which do not exclude or prevent the presence of other components, features, elements, members, steps known from or described in the prior art.

Quoting numeric intervals through the endpoints includes all integers, fractions, and / or real numbers between the endpoints, including these endpoints.

The term "refrigeration box" as used herein refers to a container, the container comprising a thermal insulation system and a refrigeration system, the refrigeration system being suitable for cooling the contents of the container.

© BE2019 / 5832 The term “sensor”, as used herein, refers to any mechanical and / or electronic system capable of detecting a physical quantity, an event or a change in the environment, whereby the sensor can send information to other electronic devices, The term "temperature sensor" as used herein refers to any sensor capable of measuring temperature. The term "cloud system" as used herein refers to any system that allows data to be accessed, where the data is not located on the electronic device from which the data query is requested, and / or to transfer data to an external server and / or store an electronic device, The cloud system can automatically store one or more measured parameters and / or logged data directly on an external server and / or an electronic device, The term "cooling device" as used herein refers to a device suitable for cooling an object, a cavity or a space, wherein the cavity or space can be surrounded by six walls and wherein the object can comprise living and / or lifeless matter.

The term "heater" as used herein refers to a device suitable for heating an object, a cavity or a space, where the cavity or space may be surrounded by six walls and the object may contain living and / or inanimate matter. The term "electrical connector" as used herein refers to any device suitable for making an electrical connection that is also easily detachable. The electrical connection is suitable for supplying power, one or more signals, or both.

The term "grid" as used herein refers to an object falling over crossed or parallel wires and gales, with the holes situated between the wires. The wires can be of a variety of shapes, thicknesses and lengths. The grid can comprise a metal material.

The term "thaw-freeze cycle" as used herein refers to a cycle in which a sample or object is first frozen and then thawed. The steel or object can

; BE2019 / 5832 can also be thawed first and then frozen. The steel can include organic and / or inorganic components.

The term "one or more thaw-freeze cycles" as used herein includes any combination of thawing and freezing, where the thawing and / or freezing is performed at least twice. For example, defrost-freeze-thaw, freeze-thaw-freeze, defrost-freeze-defrost-freeze, and so on.

The term "vibration reduction system", as used herein, refers to any system capable of eliminating or dampening vibrations in a load. The vibration reduction system can be positioned under the load, in the cooling box, or under the cooling box in which the load is transported. The vibration reduction system can, but does not have to be, part of the cooling box.

The term "valve" as used herein refers to a closable opening. The valve can have a top, a bottom and two sides. In order to be able to open and / or close the cover, the cover can comprise hinges. The hinges can be positioned along one side, top or bottom of the lid.

The term "display device" as used herein refers to a device comprising a display. The display is adapted to display the temperature of the cavity of the cooling box. The screen can comprise a touchscreen. The screen device can also comprise various buttons, the buttons being positioned next to the screen. The buttons can be used to regulate the temperature in the refrigerator box, to switch the refrigerator box on / off and / or to display logged temperatures on the screen. The buttons can also be incorporated in the touchscreen.

The term "insulation panels" as used herein refers to panels which are suitable for partially or completely thermally insulating a cavity or space, whereby the panels can take on various dimensions and / or shapes (e.g., vacuum panels).

The term "logging system" as used herein refers to any system capable of measuring and storing the temperature of the cavity of the refrigeration box during

> BE2019 / 5832 transport, in which the temperature is measured and stored every a predetermined amount of time.

The term "infrared reflective layer" as used herein refers to a layer capable of partially or completely reflecting infrared radiation. The term "Peltierslement" as used herein refers to an electrical component that can be used as a thermoelectric heat pump, wherein the electrical component uses the Peltier effect and / or the Seebeck effect.

In a first aspect, the invention relates to a thermoelectric cooling box suitable for mounting beneath a drone and / or on a motorcycle, comprising an essentially beam or cube-shaped cavity surrounded by a top wall, a bottom wall and four side walls, the cavity being of the cooling box, the cooling box further comprising the following elements: a) at least one temperature sensor suitable for recording the temperature in the cavity of the cooling box; b} at least one cooling device for actuating a thermoelectric effect suitable for cooling the cavity of the cooling box, the cooling being controlled on the basis of the recorded temperature in the cavity of the cooling box, preferably wherein the cooling box is at least comprises two, more preferably at least three cooling devices; c) at least one battery for supplying energy to the at least one cooling device, the battery line comprising an electrical connector suitable for connecting the battery to a battery of the drone and / or motorcycle; characterized in that all walls of the cooling box comprise an outer layer, an intermediate layer and an inner layer, the outer and the inner layer having a thickness between 0.3 nm and 1 cm and a hard material selected from a list comprising polyurea, polyethylene , polyurethane, polypropylene, graphene, aerograph, porous 3D form of graphene, buckypaper, carbon nanotubes, nanofibers, nanoplates, nanccellulose, aerography, wurtzite boron nitride, silicon carbide, titanium, steel, osmium, metallic glass, Kevlar, materials based on spider silk, metallic microlattice, carbyne or a combination thereof; and wherein the intermediate layer has a thickness between 0.3 nm and 10 cm and an insulating material selected from one

© BE2019 / 5832 list comprising glass fiber reinforcing plastic, mineral wool, cellulose, polyurethane, polystyrene, vermiculite, perlite, cork, keratin, cellulose based nanomaterials, airgel, polystyrene in combination with graphene powders or carbon nanotubes, or a combination thereof; preferably the outer and inner layers have a thickness between 0.5 nm and 4 mm and the outer and inner layers comprise a hard material selected from a list including polyurea, polyethylene, polyurethane, polypropylene, graphene, aerograph, porous 3D form of graphene , bucky paper, carbon nanotubes, nanofibers, nanoplates, nanoplates, nanocellulose, aerography, materials based on spider silk, metallic microlattice, carbyne or a combination thereof; and the intermediate layer has a thickness between 100 nm and 2 cm and the intermediate layer comprises an insulating material selected from the list of glass fiber reinforcing plastic, mineral wool, cellulose, polyurethane, polystyrene, cork, keratin, cellulose-based nanomaterials, airgel, graphene powders, carbon nanotubes, or a combination thereof. The preferred embodiments listed below can be combined with each other and / or with the aforementioned cooling box or replace specific components of the aforementioned cooling box.

Furthermore, the cooling box can also comprise other sensors, such as, but not limited to, a global positioning system, a vibration sensor, and a sensor suitable for registering technical errors. Each addition of a different type of sensor makes it possible to monitor the transport of the load beler, which further increases the efficiency and quality of the transport. In a preferred embodiment the outer layer has a thickness between G.3 nm and 7 mm, preferably between 1 nm and 7 mm, further preferably between 10 nm and 7 mm, still further preferably between 100 nm and 7 mm, at still further preferably between 100 nm and 4 mm, still further preferably between 500 nm and 4 mm, still further preferably between 1 µm and 4 mm, still further preferably between 10 µm and 4 mm, still further preferably between 90 µm and 4 mm, still further preferably between 200 µm and 4 mm, still further preferably between 500 µm and 4 mm, still further preferably between 500 µm and 3 mm.

In a preferred embodiment, the innermost layer has a thickness between

0.3 nm and 7 mm, preferably between 1 nm and 7 mm, more preferably between 10

> BE2019 / 5832 nm and 7 mm, still further preferably between 100 nm and 7 mm, still further preferably between 100 nm and 4 mm, still further preferably between 500 nm and 4 mm, still further preferably between 1 µm and 4 mm, still further preferably between 10 µm and 4 mm, still further preferably between 90 µm and 4 mm, still further preferably between 200 µm and 4 mm, still further preferably between 500 µm and 4 mm, with still further preferably between 500 µm and 3 mm.

In a preferred embodiment, the intermediate layer has a thickness between nm and 10 cm, preferably between 100 nm and 10 cm, more preferably between 10 500 nm and 7 cm, still further preferably between 1 µm and 7 cm, in still further preferably between 100 µm and 7 cm, bi still further preferably between 500 µm and 7 cm, still further preferably between 1 mm and 7 cm, still further preferably loops 1 mm and 5 cm, still further preferably between 1 mm and 3 cm, still further preferably between 5 mm and 3 cm, still further preferably loops 5 mm and 2 cm,

Compared to known devices, the invention comprises a more user-friendly, more efficient, better quality and safer way of transporting a load.

Today, goods must be transported faster, more efficiently and with a higher quality. Especially in the medical, pharmaceutical and biotechnology sectors, the speed and quality of the transport can be crucial. In particular, blood, organs, tissues and / or medical samples sometimes have to be very be transported quickly under the right conditions.

If the transport is not done under the right conditions, the medical loads will be declared unusable.

This leads to great waste of precious and / or life-saving resources.

In the first instance, the invention makes it possible to charge and transport loads simultaneously with a drone or motorcycle.

Motorcycles can easily maneuver between the existing heavy traffic, which can increase the efficiency of the transport.

Furthermore, the parking pressure can be avoided with the motorcycle.

The same applies as much, if not anymore, to drones.

Subsequently, the invention makes it possible to cool the cooling box in a controlled manner.

Due to the presence of one or more cooling devices, which cool on the basis of a thermoelectric effect, and a temperature sensor, it is possible to closely monitor the temperature of the cooling box and to adjust the temperature with a very high degree of accuracy.

© BE2019 / 5832 The one or more cooling elements in combination with a battery, which can be connected to a battery of the drone or motorcycle and supplied energy to the one or more cooling devices, ensure an even more efficient cooled transport. Because the battery includes an electrical connector and is continuously charged during transport with the drone or motorcycle, the cooling box can easily be removed from the drone or motorcycle, while the battery continues to cool the cooling box autonomously, This way it is ensured that the contents of the cool box remains refrigerated until its effective final destination (for example, up to an operating theater). The combination of the aforementioned elements ensures a controlled, efficient and user-friendly cooled transport, whereby a cooling temperature of below 0 ° C can be reached.

Furthermore, by being able to disconnect the cooling box, a customer can buy one or more cooling boxes and keep them with them. In this way, the customer can choose when to turn on the cool box and start cooling the load. The cool box can then be transported to the final destination via different vehicles. The advantage of transport via different vehicles is illustrated in the following example. If the urgency of the transport is very high, but the distance is too great to cover with the drone or motorcycle, the cool box can first be transported by helicopter. Since a helicopter cannot land everywhere, it may be necessary to cool box can also be transported by drone or motorcycle.

The walls of the refrigerator box comprise a three-layer composition, with an insulating material positioned between two hard layers. The composition of the walls makes it possible to obtain a thermally insulated hard cooling box. Due to the stated choice of materials, the thickness of the walls and the weight of the cooling box can be reduced. As a result, a cooling box is obtained in which the contents can be protected against heavy impacts and in which the ratio between the thickness of the walls of the kosi box and the volume of the contents of the cooling box is optimized. This allows a larger load or more loads to be transported with the same or better thermal insulation efficiency in the same cooling box dimension. Creating extra space in the cool box can also be advantageous to add additional features to the inside of the cool box without requiring a smaller volume of cargo to be transported.

The Applicant notes that the cool box could protect the contents when dropping the cool box from 4 m. Applicant further notes that the cooling box moreover had a better thermal insulation quality compared to the classically used cooling boxes. Furthermore, the applicant notes that the cooling box moreover had a better thermal insulation quality compared to the classically used cooling boxes. More efficient, higher quality and safer way of transporting a load has advantages especially in the medical sectors, where the transport can determine whether a human life can be saved or not, For example, a patient urgently needs a bio transfusion, but the hospital does not have a suitable blood more in stock. The blood must then be transported quickly from a donor center to the hospital. In addition, the blood must be transported below a certain temperature. During transport, the drone or motorcycle could be involved in an accident. The shock-resistant effect of the assembly of the cooling box ensures at that moment that the Dloed continues to provide maximum protection. A spare motorcyclist or vehicle can still bring the cooling box to its destination (because it continues to cool autonomously). By combining the cooling box, as described above, with the transport by drone or motorcycle, the chance of bringing the blood to the hospital on time can be increased. The patient's chances of survival can be increased.

The cooling devices can cool the cooling box by means of convection, conduction, radiation or a combination thereof.

Multiple cooling devices can be advantageous for various reasons. There is always a real chance that a cooling device will stop working or fail during transport, which can affect the quality of the transport. In these cases it is advantageous that the cooling box comprises at least two cooling devices, one cooling device serving as a backup and being able to take over the operation of the broken or failed cooling device. Subsequently, several cooling devices can be advantageous if a large temperature drop is to be achieved in the short term.

According to a preferred embodiment, the cooling box is specifically suitable for being attached to a drone, whereby the battery of the cooling box can be electrically coupled to the battery / accumulator / energy supply element of the drone, whereby the battery of the cooling box is supplied with energy (charging and / or a BE2019 / 5832 direct use) from the drone. The cool box is preferably attached to the drone on the underside of the drone, in order to disturb the control of the drone as little as possible.

According to a preferred embodiment, the outer and the inner layer has a thickness between 0.3 nm and 1 cm, preferably between 0.3 nm and 4 mm, more preferably between 100 nm and 1 cm, still further preferably between 1 µm and 4 mm, still further preferably between 90 µm and 3 mm, still further preferably between 500 µm and 3 mm, still further preferably between 500 µm and 2 mm. and the outer and inner layers comprise a hard material selected from a list including polyurea, polyethylene, polyurethane, polypropylene, or a combination thereof. The outer and inner layers may differ both partially and completely in their composition.

In addition to the effect of providing a better transport quality (hardness and thermal insulation), the stated specific choice of material and thickness allows to suppress the cost price of the cool box without affecting the volume of the content compared to the full volume of the cool box. In addition, the materials mentioned are easy to obtain, thereby increasing the efficiency, both in terms of time wastage and financially, According to a preferred embodiment, the intermediate layer has a thickness between

0.3 nm and 10 cm, preferably between 1 µm and 6 cm, more preferably between 109 µm and 5 cm, still further preferably between 1 mm and 3 cm, still further preferably between 5 mm and 3 cm, still further preferably between 5 mm and 2 µm, and the intermediate layer comprises an insulating material selected from a list including mineral wool, polyurethane, polystyrene, cork or a combination thereof.

The combination of the preferred thickness and composition of the outer, inner and interlayer will further increase efficiency, both in terms of time wasted and financially.

According to a preferred embodiment, the cooling box comprises a heating device for actuating a thermoelectric effect suitable for heating the cavity of the cooling box.

a BE2019 / 5832 The addition of the heating device makes it possible to also heat up the cooling box, In this way the temperature inside the cooling box can be better controlled, Many countries have severe winters or periods in which the outside air temperature can go below 0 ° C . For certain loads there is in the first instance an upper limit in terms of temperature at which they may be stored, and it is important to stay below this, but with some products there is also a certain lower limit that may be important. In this view, the presence of A heating element is therefore also advantageous to ensure this lower limit in extreme situations. An example is in some biomedical samples, where one or more dooci-freeze cycles can drastically affect the quality of the samples. The presence of the heating device makes it possible to ensure that at low outside air temperatures the load is not transported below a specific temperature.

According to a preferred embodiment, the refrigeration box comprises an electrical circuit, encompassing a central processing unit, suitable for controlling the one or more refrigeration devices on the basis of the recorded temperature in the cavity of the refrigeration box.

The electrical circuit can register the temperature in the cavity of the cooling box and in an autonomous way switch on the one or more cooling devices if the temperature is above the desired temperature or switch off if the temperature of the cavity of the refrigerator box is equal to the desired temperature. . If the refrigeration box includes multiple refrigeration devices, the electrical circuit can autonomously decide how many refrigeration devices should be turned on to maximize the quality of the transport. The electrical circuit can also control the operation of the heater in an autonomous manner.

According to a preferred embodiment, the cooling box comprises at least one grid positioned on at least one outer surface of the cooling box where one or more of the cooling devices are positioned, suitable for dissipating the heat generated by the at least one cooling device, preferably with all cooling devices on the side provided with the grille. According to a preferred embodiment, the at least one cooling device and the at least one grille are positioned on a side wall which is distal to the handlebars of the motorcycle.

BE2019 / 5832 According to a preferred embodiment the at least one cooling device and the at least one grille are positioned on a side wall which is located distal to the front of the drone.

Alternatively, the sidewall grille can be positioned proximal to the front of the drone or the handlebars of the motorcycle. With the drone, this can be particularly useful to make use of incoming air currents that ensure a good flow.When an object moves forward, a low pressure area is automatically created in a space behind the object by the sudden departure of the volume of the object in that space, Due to the specific positioning of the grille, use is made of this low-pressure area at the rear of the cooling box, where the grille is located. The difference in pressure ensures that warm air generated by the one or more cooling devices is better extracted towards the rear of the motorcycle or drone, towards the created low-pressure area. The extraction of the heat can reduce the risk of heat build-up, and ensures that the cooling can proceed more efficiently. This can increase the life of the one or more cooling devices and any other electronic components. Moreover, overheating of the driver's back can be prevented in motorcycles. In a preferred embodiment, the heater is positioned on one side wall which is distal to the handlebars of the motorcycle. According to a preferred embodiment, the heater is positioned on one side wall which is located distal to the front of the drone. The combination of the preferred embodiments, wherein the at least one cooling device, the heater and the at least one grid are positioned on a sidewall, which is located distal to the handlebars of the motorcycle or to the front of the drone, is especially advantageous. The Applicant noticed that positioning the heater and cooling devices on a side wall provided better uniformity of the temperature distribution of the air circulation.

> BE2019 / 5832 most electrical elements are advantageous for the simplicity of the construction and the possible repair of the cooling box. The simpler the electrical construction of the cool box, the easier it is to train the motorcycle drivers to repair the cool box themselves in urgent circumstances.

In a preferred embodiment, the sidewall, located distal to the handlebars of the motorcycle or distal to the front of the drone, comprises at least one grid comprising the at least one cooling device, the at least one grid comprising the at least one koslin direction, can be removed from the side wall. The advantage of the removable grid is that it is even easier to maintain and / or replace the at least one cooling device. In a preferred embodiment, the side wall, located distal to the handlebars of the motorcycle or distal to the front of the drone, comprises a removable panel, the panel overturning the at least one battery. According to a preferred embodiment, the cooling box comprises a vibration reduction system suitable for damping vibrations in a load. The addition of a vibration reduction system makes it possible to further improve the quality of the transport. During the transport of a load in a refrigerated box, and especially during transport with a motorcycle or drone, a lot of vibrations arise in the load. These vibrations can affect the load. Biological samples are particularly sensitive to this. It is important to dampen these vibrations as much as possible. In a preferred embodiment, the vibration reduction system is positioned in the cavity of the cooling box on top of the bottom wall, with the charge placed on top of or in the vibration reduction system. The applicant has found that especially the vibration reduction system, as mentioned above, is suitable for damping the vibrations in the cargo. Applicants' vibration reduction system includes a simple mechanism that can be easily removed from the cooling box if desired. In addition, the applicant has found that its vibration reduction system is better suited to dampen vibrations and thus increase the quality of the transport.

According to a preferred embodiment, the vibration reduction system comprises a box, encompassing a cavity surrounded by six surfaces, and at least one gel material, the box being placed in the cavity of the cooling box, and the gel material being located between the cooling box and the box and / or wherein the gel material is disposed on at least one inner surface of the walls of the refrigerator box and / or at least one outer surface of the walls of the box.

The applicant has found that the vibration reduction system, as described in the previous two paragraphs, dampens the vibrations more efficiently.

According to a preferred embodiment, the box comprises one or more, preferably at least two, recesses or irregularities on at least one inner surface.

More preferably, the box comprises one or more, preferably at least two, recesses or irregularities on at least three inner surfaces.

Applicant notes that one hollow or bump is enough to improve air circulation within the cavity of the box.

It is further noted that the more recesses or unevennesses the box has, the better the air is circulated within the cavity of the box, the more efficiently cooling the contents of the cooling box.

According to a preferred embodiment, the vibration reduction system comprises a gel material and a removable plate, the removable plate being located parallel to the bottom wall in the cavity of the cooling box, and the gel material being positioned between the bottom wall and the removable plate.

The vibration reduction is achieved by placing the load on top of the removable plate.

Furthermore, instead of between the bottom wall and the removable plate, the gel material may be located on the inner surface of the bottom wall.

In an alternative embodiment, the squeezable plate may comprise the gel material, the gel material being disposed on a surface.

In some cases, the load itself may include a vibration reduction system, which may make adding an additional vibration reduction system unnecessary.

In these cases or in cases where stabilization of the load is not desired, extra space can be created in the cavity of the BE2019 / 5832 due to the detachability of the vibration reduction system.As a result, a larger load or several loads can be transported turn into.

According to a preferred embodiment, the vibration reduction system comprises a plate or loading surface (removable or not) and one or more gyroscopes, the loading surface being mounted on the gyroscopes. The vibration reduction system coupled to the one or more gyroscopes will ensure a transport that is always level and free from vibrations as much as possible. Preferably, the cooling box comprises a number of gyroscopes, preferably 2, more preferably 4, wherein the charging surface is movably provided in the cooling box and coupled to the gyroscopes for stabilizing the charging surface.

In a preferred embodiment, the removable plate comprises one or more pockets or imperfections, the pockets or irregularities being disposed on the surface proximal to the load. According to a preferred embodiment, the motorcycle, drone and / or the cooling box comprises a vibration reduction system, the vibration reduction system being suitable for damping vibrations arising in the cooling box during transport with the motorcycle or drone. The general reduction of vibrations can be further improved if the vibration reduction system inside the cavity of the cooling box is combined with the vibration reduction system present on the motorcycle or drone, on the outside of the cooling box or between the motorcycle / drone and the cooling box.

According to a preferred embodiment, the top wall comprises at least one flap suitable for opening the refrigeration box.

According to a preferred embodiment, the top wall comprises an opening system suitable for opening the refrigerator box by pulling the top wall open along one side.

According to a preferred embodiment, one of the side walls, positioned parallel to the length of the motorcycle or parallel to the longitudinal axis of the drone (taking into account the allocation of a front

> BE2019 / 5832 and rear as viewed from the driver's perspective), a flap in the top half of the side wall suitable for opening the cool box.

In a specific preferred embodiment, the valve is positioned in the top half of the side wall, positioned parallel to the length of the motorcycle or the longitudinal axis of the drone and optionally positioned directly opposite the side where the side stand of the motorcycle stands.

The Applicant has found that when the lid for opening the refrigeration box is placed in the top half of the refrigeration box, less cold air flows away to the environment when the refrigeration box is opened.

As a result, the cooling efficiency is increased.

According to a preferred embodiment, one of the side walls, positioned parallel to the length of the motorcycle or the longitudinal axis of the drone, comprises two flaps suitable for opening the refrigeration box, one of which is positioned in the upper half of the side wall and wherein the other valve is positioned in the lower half of the side wall.

The flaps can be positioned such that when both flaps are opened the whole side wall of the refrigerator box is open.

According to a specific preferred embodiment, the flaps are positioned in the top half of the side wall, positioned parallel to the length of the motorcycle or the longitudinal axis of the drone and optionally positioned directly opposite the side where the side stand of the motorcycle stands, In order to be able to insert larger loads or to easily insert the vibration reduction system comprising a box into the cooling box or to easily remove it from the cooling box, it is advantageous that one wall can be completely opened up.

The two-valve system allows to exploit the advantages of the valve positioned in the top half of the refrigerator box, if it is not desired to open the entire wall of the box.

The two-valve system ensures that there is a balance between user-friendliness, cleaning and efficient cooling of the content.

Positioning one or more flaps directly opposite the side of the motorcycle's side stand prevents the load from sliding out when the cool box is opened.

According to a preferred embodiment, the cooling box comprises a display device suitable for displaying the temperature of the cavity of the cooling box and the display device comprising a function suitable for controlling the temperature of the cavity of the cooling box from the display device. embodiment, where the cooling box also comprises other sensors in addition to the temperature sensor, the display device may also be suitable for displaying other parameters, such as, but not limited to, the condition of the battery, the global positioning system location, the vibrations present in the cooling box, status of the cooling elements and / or any technical errors. The display device increases the accuracy of the temperature monitoring of the cool box cavity. Furthermore, the display device allows to easily control the temperature of the cow box cavity. In this way, the quality of the transport is increased. According to a preferred embodiment, the display device is positioned on the handlebars of the motorcycle. Alternatively, the display device is provided on a control means for the drone (such as a screen on the controller or the operator's display). Driving a motorcycle requires a high level of attention from the driver. Positioning the display device on the handlebar of the motorcycle facilitates monitoring of the cool box cavity temperature without distracting the driver. The combination of the cooling box comprising a display device and the positioning of the display device on the handlebars of the motorcycle or on the control means of the drone is especially advantageous. The quality of the transport is increased because the temperature can be checked more frequently and more user-friendly and, if necessary, adjusted.

In an alternative embodiment, the display device is replaced by an electronic device comprising a display, such as, but not limited to, a digital mobile phone or a tablet, the electronic device being adapted to display the one or more said parameters.

According to a preferred embodiment, at least two, preferably at least three, more preferably at least four inner surfaces of the cooling box each comprise an insulating layer.

According to a preferred embodiment, at least two, preferably at least three, more preferably at least four inner surfaces of the cooling box topple over and at least two insulation panels.

By adding an insulation layer or insulation panels, the thermal insulation of the cooling box can be improved, Improving the thermal insulation leads to more efficient use of the battery, which can increase the life of the battery, The battery life has mainly importance for the possibility of autonomously cooling and / or heating the cavity of the cooling box. Furthermore, the efficiency of the cooling and / or heating is also increased.

According to a preferred embodiment, at least two, preferably at least three, more preferably at least four inner surfaces of the cooling box each comprise at least one bump or recess.

According to a preferred embodiment, at least two, preferably at least three, more preferably at least four inner surfaces of the cooling box each comprise at least one groove, crease, ripple, pit, bulge, cut or a combination thereof, by providing recesses or unevenness, the air circulation within the cavity of the cooling box is improved, whereby an increased efficiency in cooling and / or heating the cooling box is obtained.

According to a preferred embodiment, the cooling box comprises a logging system suitable for logging the temperature trend in the cavity of the cooling box,

* = BE2019 / 5832 Keeping track of the temperature trend of the cavity of the cooling box is advantageous because the quality of the transport can be checked.

Especially in the medical, biomedical and pharmaceutical sectors it is of great importance that it can be confirmed whether the samples, organs and / or tissues have been transported under the correct temperature.

In an alternative embodiment, where the cooling box also includes other sensors in addition to the temperature sensor, the logging system may also be suitable for logging other parameters, such as, but not limited to, the battery condition, the global positioning system location, the vibrations present. in the cooling box, status of the cooling elements and / or any technical errors.

The more parameters that are logged, the cheaper for the customer and the applicant.

The customer receives more information about the transport conditions of his / her cargo, while the applicant can better monitor the transport and thus better identify malfunctions and / or errors and further optimize the transport.

According to a preferred embodiment, the logging system comprises a printer device suitable for printing the temperature profile.

Because the temperature trend can be printed, a printed proof of the quality of the transport can be given to a customer or an intermediary.

This allows the customer to be assured that his cargo has been transported under the correct temperature.

Furthermore, if the cargo has not been transported under the correct temperature, the customer can estimate whether or not his cargo is still usable or to what extent it is still usable.

In this way, wasted time on the part of the customer can be avoided. An example can be found in the transport of many antibodies. Leaving antibodies above 12 ° C for a few minutes can cause them to no longer have the desired effect.

If the customer does not know that the antibodies were transported under the wrong temperature, he / she could lose hours or even days trying to figure out why the antibodies are not working the way they should.

This is certainly problematic if the antibodies are part of a large experiment, and the experiment continues to fail. In that case it is very difficult to identify because there could be a potential problem, causing the client to lose a week or more.

© BE2019 / 5832 A thermoelectric cooling box according to any one of the preceding claims, characterized in that the logging system comprises a communication module, suitable for communicating (preferably via Wi-Fi) with an external storage device, for example an external server and / or an external electronic device and / or a cloud storage system, and suitable for automatically sending a logged temperature trend to the external storage space and whereby the external storage space keeps track of the logged temperature trend. Note that the progression can also be kept of other parameters in and / or outside the cavity of the cooling box, for example one or more of the following parameters: air humidity, air pressure, air quality {contaminants}, vibration, battery capacity, position (GPS) , operation of the individual elements of the refrigerator box. For this purpose, additional components are added or not, in particular suitable sensors for recording the parameters.

Direct printing of the transport progress is not always self-evident, especially if the progress of several parameters has to be printed. One of the limiting factors is the provision of paper. To have paper in stock, extra space must be provided in or at the cool box. Today, the printing of information on paper is preferably avoided, as printing information on paper is not ecologically sound. In addition, a printed copy can always be lost. Storage via a cloud system would be cheaper for the reasons stated above. Logged data can be sent to the customer via email after transport. In an alternative / additional embodiment, the customer can access the cloud system in which to download the logged data. In another (alternative or additional) embodiment, the customer can receive a login that takes him / she to a page in which the log data of all his / her orders can be viewed and / or downloaded. The communication module is preferably a part of the cooling box, whereby the communication module is suitable for sending the one or more logged parameters to the external storage space (external server, cloud storage and / or the external electronic device). According to a preferred embodiment, the cooling box comprises a channel suitable for removing moisture that forms in the cavity of the cooling box.

Condensation can form in the cavity of the cool box. During the transport of biomedical / medical samples, tissues or organs, moisture is not desirable

© BE2019 / 5832 is still present in the cool box, as mold can grow in the condensation. By providing a channel to the outside, the moisture can be transported away from the cool box. The channel may be present as a hole in the bottom wall of the refrigerator box. The direction of the channel may be positioned perpendicular to the bottom wall. In an alternative embodiment, the channel may include a direction, where the direction is not perpendicular or parallel to the bottom wall. Furthermore, the circumference of the cross-section of the channel may change throughout the length of the channel, For example, the circumference of the cross-section of the channel may decrease gradually or abruptly outwardly. It may also be that the channel is part of a channel system. , suitable for removing moisture. The channel system may further include one or more slots with or without a ramp suitable for guiding moisture to the channel. The slots may be on the bottom wall and / or in at least one side wall.

According to a preferred embodiment, the cooling box comprises at least one, preferably several, plates, positioned on the inside of the cooling box for the at least one cooling device, the plate being adapted to transport the cold air, from the at least one cooling device, to the top wall of the deflect the cool box. The cold air can then descend around the cargo via the side walls.

This prevents the cold air from reaching the load directly, resulting in better uniform cooling. In one embodiment the plate can be connected to the channel or to the channel system.

According to a preferred embodiment, the cooling box comprises one or more solar panels for providing energy to the at least one cooling device. The one or more solar panels can also provide energy to the heating device.

The one or more solar panels can be mounted on top of the cool box and / or on the side walls of the cool box. The one or more solar panels can be connected to the battery via an electrical connector and charge the battery, and / or they can be directly connected to the one or more cooling devices and / or the heating device.

The one or more solar panels can be especially useful in the summer months or in countries where it is often sunny and warm, when the cooling box has to be cooled more, and therefore more energy supply has to be provided. Furthermore, the one or more solar panels can be used as a backup. should the motorcycle or

> BE2019 / 5832 drone cannot supply energy or if the cooling box has to work autonomously for a longer period of time. According to a preferred embodiment, at least four outer surfaces of the walls of the cooling box are provided with a coating comprising an infrared reflective layer. The addition of the coating ensures that the thickness of the walls of the cooling box can be reduced without affecting the thermal insulation of the cooling box. the cool box is lowered. The coating can be painted or sprayed onto the outer surfaces of the walls of the cool box. The coating may comprise nanoparticles and may have a thickness between 0.3 nm and 1 cm, preferably between 10 nm and 1 cm, further preferably between 10 nm and 1 mm, still further preferably between 10 µm and 1 mm. In a preferred embodiment the one or more cooling devices comprise at least one Peltier element. The one or more cooling devices may comprise a cooling plate suitable for radiating the heat generated by the Peltier element over a larger area. The one or more cooling devices may comprise one or more fans positioned on the cold side of the Peltier element, the fans being suitable. for better circulation of the generated cold air. The one or more cooling devices may comprise one or more fans positioned on the warm side of the Pellierelerment, the fans being adapted to better dissipate the generated warm air. Cooling plates may be present between the Peltier elements and the one or more fans, present on the cold side, warm side or on both sides of the Peltier element. The function of the cooling plates is to spread the cold and / or warm air over a larger surface, so that the one or more fans can circulate the cold and / or warm air more efficiently.

In a second aspect, the invention relates to a method for controlling the temperature of a thermoelectric refrigeration box suitable for mounting on a motorcycle or under a drone, the refrigeration box having an essentially beam or cube-shaped cavity surrounded by a top wall, a bottom wall and four side walls, at least one cooling device, a heater, a battery comprising an electrical connector and a temperature sensor, the method comprising the steps of:

*> BE2019 / 5832 a. Mounting the cooling box on the motorcycle or under the drone; b. connecting the battery to a battery of the motorcycle or drone via the electrical connector, the battery being powered by the battery; c controlling the temperature of the refrigeration box to a predetermined temperature, the controlling comprising cooling and / or heating the cavity of the refrigeration box using the at least one cooling device, the heating device and the temperature sensor, the energy source being for cooling and / or heating comes from the battery, the battery being suitable for autonomously cooling the cooling box for a certain period of time. In what follows, the invention is described by means of non-limiting examples or figures illustrating the invention, and which are not intended or should not be construed to imitate the scope of the invention.

DESCRIPTION OF THE FIGURES Figures 1, 2, 3, 4 and 5 show a number of perspectives of a cooling box (1) according to the invention. Note that these do not necessarily all occur in combination with each other, in other words that Figure 1 shows a perspective view from the side of a first cool box, and Figure 3 shows a perspective view of one side of another cool box. However, it should be understood that the combination of the provided figures does form part of the description, just as much as figures separately. Figure 1 shows a cooling box (1) with a number of cooling devices (2) at the rear, as well as a heating device (4), and in which a grid (3) is provided at this rear above the cooling and heating devices. Note that said grille is optional, or can be replaced by another, open structure (for example full plate with one or more openings at the level of cooling devices and / or heating devices). The refrigerator box is herein provided with a public side wall by means of two independently manipulable flaps (12, 13), one on the top half of the said side wall, the other in the bottom half. It should be noted that these valves are preferably located on the side of the box die

© BE2019 / 5832 is opposite on the side of the motorcycle with the upright, so that the opening does not face down. Figure 2 shows a perspective view of the inside of a cooling box, building on Figure 1, wherein a number of plates or deflection panels (6) are provided on the inside of the cooling box at the level of the cooling devices, which optimally control the incoming cold air flow. In this case, inferior to the cooling devices {2}, a drain (7) is provided for collecting and removing condensation moisture.

Figure 3 shows a cooling box (1} on one side where the batteries (14) are provided in the wall. Furthermore, a communication module (5) is also provided in / on the wall. Figure 4 shows an embodiment of the cooling box (1 ) wherein a vibration-reducing system (8, 9, 10} is provided, namely a loading platform (8) on which the cargo can be positioned, which rests on a gel pack (9). Finally, 4 gyroscopic sensors / actuators {10} are provided which can stabilize the loading platform (8) and / or gel pack (9) in deflection of balance positions as well as compensate for vibrations Figure 5 finally shows the inside of a refrigeration box according to the invention Note that the inner walls (specifically the side walls) are provided of a ribbed / grooved pattern with protruding ribs (15) defining grooves (16), in this case vertical (although horizontal grooves are equally possible), this structure ensures that air currents remain possible in the grooves (16) for cooling / warming,even with a quasi-complete filling of the cavity of the cooling box, In a specific embodiment according to Figure 5, parts of the side wall can be removed in order to be able to reach back pieces, for example insulation panels, and be replaced, whereby the grooves and ribs preferably connect as correctly as possible to neighboring grooves and ribs. Note that this removable character is purely optional.

Claims (21)

CONCLUSIONS A thermoelectric cooling box {1} suitable for mounting under a drone and / or on a motorcycle, comprising an essentially beam or cube-shaped cavity surrounded by a top wall, a bottom wall and four side walls, the cavity of the cooling box is cooled, wherein the cooling box further comprises the following elements: a. At least one temperature sensor suitable for registering the temperature in the cavity of the cooling box; b. at least one cooling device (2) for actuating a thermoelectric effect suitable for sealing the cavity of the cooling box, wherein the cooling is controlled on the basis of the recorded temperature in the cavity of the cooling box, preferably whereby the cooling box is at least two, more preferably at least three, cooling devices around; c. at least one battery (14) for supplying energy to the at least one cooling device (2), the battery comprising an electrical connector suitable for connecting the battery to a battery of the drone and / or motorcycle; characterized in that all walls of the cooling box comprise an outer layer, an intermediate layer and an inner layer, the outer and the inner layer having a thickness between 0.3 nm and 1 cm and a hard material selected from a list comprising polyurea, polyethylene , polyurethane, polypropylene, graphene, aerographene, porous 3D form of graphene, buckypaper, carbon nanotubes, nanofibers, nanoplaations, nanoplays, nanocelluiosis, aerographite, wurtzite boron nitride, silicon carbide, titanium, steel, osmium, metallic glass, Kernevlar, materials , metallic microlattice, carbyne or a combination thereof; and wherein the intermediate layer has a thickness between 0.3 nm and 10 cm and an insulating material selected from a list including glass fiber reinforcing plastic, mineral wool, cellulose, polyurethane, polystyrene, vermiculite, perlite, cork, keratin, cellulose based nanomaterials, airgel, polystyrene in combination with graphene powders or carbon nanotubes, or any combination thereof; preferably the outer and inner layers have a thickness between 0.3 nm and 4 mm and the outer and inner layers comprise a hard material selected from a list including polyurea, polyethylene, polyurethane, polypropylene, graphene, aerograph, porous 3D form of graphene, bucky paper, carbon nanotubes, nanofibers, nanoplates, nanoplates, nanocellulose, aerography, materials based on spider silk, metallic microlattice, carbyne or a combination thereof; and the intermediate layer has a thickness between 100 nm and 2 cm and the intermediate layer comprises an insulating material selected from the list comprising glass fiber reinforcing plastic, mineral wool, cellulose, polyurethane, polystyrene, cork, keratin, cellulose-based nanomaterials, airgel, graphene powders. , carbon nanotubes, or a combination thereof; and wherein the refrigeration box comprises a logging system suitable for logging the temperature trend in the cavity of the refrigeration box. A thermoelectric refrigeration box according to the preceding claim 1, wherein the refrigeration box is suitable to be mounted under a drone, preferably detachably mounted. A thermoelectric refrigeration box according to the preceding claim 1, wherein the refrigeration box is adapted to be mounted on a motorcycle, preferably detachably mounted. A thermoelectric refrigeration box according to any one of the preceding claims, characterized in that the outer and inner layer has a thickness between 0.5 and 4 mm and comprises a hard material selected from a list comprising polyurea, polyethylene, polyurethane, polypropylene or a combination thereof. ; and wherein the intermediate layer has a thickness of between 1mm and 2cm and comprises an insulating material selected from a list including mineral wool, polyurethane, polystyrene, cork or a combination thereof; A thermoelectric refrigeration box according to any one of the preceding claims, wherein the refrigeration box comprises a heating device (4) for actuating a thermoelectric effect suitable for heating the cavity of the refrigeration box, A thermoelectric refrigeration box according to any one of the preceding claims, comprising at least one grid (3) positioned on at least one outer surface of the refrigeration box where one or more of the cooling devices are positioned, suitable for dissipating the heat generated by the at least one cooling device. A thermoelectric cooling box according to the preceding claim 4, characterized in that the at least one cooling device and the at least one grille (3) are positioned on one side wall which is located distal to the handlebars of the motorcycle or distal located in relation to the front of the aircraft. A thermoelectric refrigeration box according to any one of the preceding claims, characterized in that the refrigeration box comprises a vibration reduction system suitable for damping vibrations in a charge, preferably wherein the vibration reduction system is positioned in the cavity of the cooling box on top of the bottom wall, wherein the load is placed on top of or in the vibration reduction system. A thermoelectric refrigeration box according to any one of the preceding claims, characterized in that the vibration reduction system comprises a box, comprising a cavity surrounded by six surfaces, and at least one gel material, the box fitting into the cavity of the cooling box, preferably wherein the box is placed in the cavity of the cool box, and wherein the gel material is located between the cow box and the box or the gel material is placed on at least one inner surface of the walls of the cool box and / or at least one outer surface of the walls of the box. A thermoelectric refrigeration box according to any one of the preceding claims, characterized in that one of the side walls, positioned parallel to the length of the motorcycle or parallel to the longitudinal axis of the drone, has a flap in the upper half of the side wall. includes suitable for opening the cool box. 11. A thermoelectric cooling box according to any one of the preceding claims, characterized in that the cooling box comprises a display device suitable for displaying the temperature of the cooling box and wherein the display device comprises a function suitable for controlling the temperature of the cavity of the the cooling box from the display device, preferably wherein the display device is positioned on the steering wheel of the motorcycle or on a control means for controlling the drone. 12. A thermoelectric refrigeration box according to any one of the preceding claims, wherein at least two inner surfaces of the refrigeration box each comprise at least two insulation panels, preferably wherein at least three, more preferably at least four inner surfaces of the refrigeration box each have the at least two insulation. panels. A thermoelectric refrigeration box according to any one of the preceding claims, wherein at least two inner surfaces of the refrigeration box each comprise at least one groove, crease, ripple, pit, cut, or a combination thereof, preferably wherein at least three, more preferably at least four interior surfaces of the refrigeration box each include the at least one groove, crease, ripple, pit, cut (16), or a combination thereof. A thermoelectric cooling box according to any one of the preceding claims, wherein the logging system comprises a printer device suitable for printing the temperature trend. A thermoelectric refrigerator box according to any one of the preceding claims, comprising a communication module (5) suitable for communicating with an external storage device for keeping data, preferably via cloudopsiag and / or via one or more external servers, wherein the communication module (5) automatically logs a temperature trend in the cavity of the refrigerator box and forwards it to the external storage device for storage. A thermoelectric refrigeration box according to any one of the preceding claims, wherein the refrigeration box comprises a channel suitable for draining away moisture that forms in the cavity of the refrigeration box. A thermoelectric refrigeration box according to any preceding claim, wherein the refrigeration box comprises at least one solar panel for providing energy to the at least one refrigeration device. se BE2019 / 5832 A thermoelectric refrigeration box according to any one of the preceding claims, wherein at least four outer surfaces of the walls of the cooling box are provided with a coating comprising an infrared reflective layer. A thermoelectric cooling box according to any one of the preceding claims, wherein the cooling device comprises at least one Peltier element, wherein the at least one Peltier element is suitable for cooling, A thermoelectric refrigeration box according to any one of the preceding claims, wherein the refrigeration box comprises one or more, preferably 2, more preferably 4, gyroscopes (10), and wherein the refrigeration box comprises a loading surface in the cavity, the loading surface being movable. is provided in the cooling box and is coupled to the gyroscopes (10) to stabilize the loading surface, 21. A method of controlling the temperature of a thermoelectric refrigeration box (1) suitable for mounting on a motorcycle or under a drone, wherein the cooling box has an essentially cuboidal or cubic cavity surrounded by a top wall, a bottom wall and comprises four side walls, at least one cooling device {2}, a heating device (4), a battery (14) comprising an electrical connector and a temperature sensor, the method comprising the steps of: a. mounting the cooling box on the motorcycle or underneath the drone; b. connecting the battery to a battery of the motorcycle or drone via the electrical connector, the battery being powered by the battery; c. controlling the temperature of the refrigeration box to a predetermined temperature, the controlling comprising cooling and / or heating the cavity of the refrigeration box using the at least one cooling device, the heating device and the temperature sensor, the energy source for the cooling and / or heating originates from the battery, the battery being suitable for autonomously cooling the cooling box for a specific period of time.