JP2017503136A - External module device that automatically adjusts the temperature of the enclosure - Google Patents

Abstract

The present invention relates to a modular device for regulating temperature, which can be associated with at least one storage enclosure (1). This device comprises a thermochemical system comprising a tank (13) containing a liquefied gas that can be combined with the reaction product contained in the reactor (9) after evaporation, the device comprising: -Storage Enclosure- In order to heat the jar (1), the reactor compartment (10) is in communication only with the storage enclosure (1), while at the same time the evaporator compartment (14) is in communication with the outside of the device, 1) switching means that allows the evaporator compartment (14) to communicate with the storage enclosure (1) only to cool the reactor compartment (10) at the same time as it cools the reactor compartment (10). It is characterized by providing. [Selection] Figure 2

Description

  The present invention relates to an external modular device for automatically adjusting the temperature of an enclosure consisting of an isothermal container, of the type intended to transport goods that are particularly sensitive to heat.

  To ensure a low-temperature distribution system, this type of enclosure can generate cold air during transportation because the enclosure may be exposed to low temperature conditions that require its heating. It is known that this is not enough. For example, this applies to an enclosure containing a heat sensitive product, in which case it is essential to maintain the product between 2 ° C. and 8 ° C., during which the product is Is exposed to an external temperature of −10 ° C. and at another time to a temperature of 30 ° C.

  When the enclosure is composed of a large-capacity container, a refrigeration unit is usually used, and the evaporator can supply the enclosure with a negative calorie necessary for cooling, and a high-temperature pressurized fluid. Is allowed to flow through the evaporator to supply the calories necessary for the heating.

  However, such devices can only be used for high capacity enclosures, especially for weight and size reasons. Moreover, the system must be permanently connectable to an electrical energy source, which naturally complicates the transportation problem. Furthermore, the use of an evaporator as a means for generating heat is only possible in certain types of refrigeration units. Finally, such devices can only function in cold or heat generating modes, but changing from one mode to the other is sensitive to certain heat. Presents the risk of thermal shock, which can compromise the integrity of the product.

  In addition, these devices are usually integrated into a temperature-controlled enclosure and constitute an assembly that is inseparable from the enclosure. Thus, for example, it can be arranged in several types of containers so that the output of the adjusting device can be adapted to the output required by, for example, the nature of the product being transported and the weather conditions encountered during the transport. It is useful to be able to have a temperature control device that can.

  The object of the present invention is to propose an external device for maintaining the temperature of the enclosure, which can possibly be removably attached to the enclosure, the internal temperature of the enclosure being given Must be kept at the setpoint, the enclosure is completely self-contained from an energy point of view, and the enclosure performs its regulation function regardless of the external temperature profile to which the enclosure is exposed The device is also modular and adaptable to the enclosure to be adjusted.

Accordingly, an object of the present invention is a modular device that can be attached to at least one storage enclosure and automatically adjusts the temperature to a specific set point. The apparatus comprises a thermochemical system comprising a tank, possibly containing a liquefied gas, which can be combined with a reaction product contained in the reactor after evaporation according to an exothermic thermochemical reaction. A housing containing the reaction product, the resulting reaction product can be regenerated by heating according to a reverse thermochemical reaction, releasing the gas, and the reactor and evaporator of the thermochemical system are The means for heating and cooling the enclosure are respectively configured and arranged in the reactor compartment and the evaporator compartment made in the housing, respectively, and the device is arranged in the housing and:
-Communicating the reactor compartment only with the storage enclosure to heat the storage enclosure, while at the same time communicating the evaporator compartment with the outside of the device;
-Characterized in that it comprises switching means capable of communicating the evaporator compartment only with the storage enclosure to cool the storage enclosure and at the same time communicating the reactor compartment with the outside of the apparatus. .

  Advantageously, the housing includes means for attaching to the enclosure. The attachment means is not limited according to the present invention. The housing is a strap that is secured to the housing and can be wrapped around the enclosure, hooks that cooperate with complementary means located on the outer surface of the enclosure, or Any other attachment means may be included that allows the jar to be preferably removably attached.

  In one embodiment of the present invention, the apparatus can include means capable of communicating the reactor compartment and the evaporator compartment simultaneously with the storage enclosure.

  The apparatus according to the invention can comprise an inlet duct and an outlet duct that can be connected to the inlet and outlet of the reactor compartment and the inlet and outlet of the evaporator compartment, respectively, which inlet duct and outlet duct are connected to the storage enclosure. -It can be connected to the outlet and inlet of the jacket.

  According to the invention, the reactor compartment and / or the evaporator compartment comprise means capable of activating the circulation of air flow through the compartment.

  The reactor compartment may include an intake valve and an outlet valve, each of the intake and outlet valves being in an open position where the reactor compartment communicates with the exterior and a closed position where the reactor compartment is isolated from the exterior. The evaporator compartment can include an intake valve and an outlet valve, each of the intake valve and the outlet valve is in an open position where the evaporator compartment communicates with the outside, and the evaporator compartment It is possible to maintain a closed position where is isolated from the outside.

Furthermore, the device according to the invention has two reversing valves, ie three positions:
A first position where the inlet and outlet of the evaporator compartment are each in communication with a storage enclosure;
A second position where the inlet and outlet of the reactor compartment are each in communication with a storage enclosure;
-It may include an intake valve and an outlet valve in which the valve is in an intermediate position and is capable of maintaining a third position in which the inlet and outlet of the reactor compartment and the evaporator compartment are in communication with the storage enclosure, respectively. is there.

  The device according to the invention can be arranged in the upper part or the lower part of the storage enclosure. The apparatus can also be mounted between two storage enclosures, one of the enclosures being connectable to the reactor to be heated and the other to the evaporator to be cooled. Connectable.

  The apparatus according to the invention can be arranged such that the reactor compartment can be in communication with the first enclosure and at the same time the evaporator compartment can be in communication with the second enclosure.

  Advantageously, the reactor compartment is formed in communication with the first enclosure, and at the same time the evaporator compartment is formed in communication with a second enclosure. Advantageously, the apparatus comprises at least a first enclosure to which the housing is attached. The housing can be attached to the upper portion of the first storage enclosure. Such an arrangement facilitates the installation and removal of the device according to the invention from the enclosure; the device can be installed or removed without moving the enclosure.

  Advantageously, the apparatus comprises a second storage enclosure, the reactor compartment being in communication with the first enclosure, and at the same time the evaporator compartment being in communication with the second enclosure. Is done. One embodiment of the present invention will now be described by way of non-limiting example with reference to the accompanying drawings.

4 is a graph showing an example of a temperature profile that can expose a container equipped with a device according to the present invention during a transport operation; FIG. 2 is a schematic view of a container equipped with a device according to the invention in a cold air generating mode. FIG. 3 is a schematic view of the container shown in FIG. 2 and the device according to the invention in a heat generating mode. FIG. 4 is a schematic view of the container and the device according to the invention shown in FIGS. 2 and 3 in a mode in which heat and cold are generated simultaneously. FIG. 2 is a schematic diagram showing various modes of attaching the apparatus according to the present invention to a container. FIG. 2 is a schematic diagram showing various modes of attaching the apparatus according to the present invention to a container. FIG. 2 is a schematic diagram showing various modes of attaching the apparatus according to the present invention to a container.

The device according to the invention maintains the enclosure containing a heat-sensitive product at a certain constant temperature _Tc for a given period, for example regardless of the weather conditions in which the enclosure may be exposed during transport. Designed to allow that.

  Shown in FIGS. 2 to 5 is an enclosure 1 intended to contain a heat sensitive product 3 and on its upper part for receiving an automatic temperature control device 2 according to the invention. It is an example of the container to perform.

  The apparatus comprises a housing 22 (shown in phantom in FIGS. 2 to 4) containing a known type of thermochemical system, which can be realized with salt and various gases, It consists essentially of a reactor 9 containing a reagent, in particular mixed with an expanded binder composed of expanded natural graphite, which in this case is manganese chloride, and the apparent density of the graphite is preferably from 50 kg / m 3 to The weight ratio of manganese chloride to expanded natural graphite is preferably 50% to 90%.

  The term “apparent density of expanded natural graphite” refers to the density calculated by the following formula for the final product to be compressed: (mixed with a given mass of reagent to obtain the product to be compressed. Natural graphite mass) / the volume of the element obtained by compressing a mixture of the natural graphite mass mentioned above and the given mass reagent mentioned above.

  The reactor 9 communicates with the tank 13 under the control of the control valve 11, and a specific gas composed of ammonia is stored in the tank 13, and the tank functions in this case as an evaporator.

  Reagents and gases can be absorbed by the reagent during the so-called operating phase by an exothermic thermochemical reaction, thereby producing a reaction product, and then the reaction product is heated by an inverse thermochemical reaction. It is like returning the reaction product during the so-called regeneration step.

  Therefore, when the reactor 9 and the evaporator 13 are communicated with each other, the liquid gas contained in the evaporator evaporates, thereby absorbing a specific amount of heat, thereby becoming a source of cold air, and the gas becomes a reagent. And thus generate an exothermic chemical reaction, and the reactor thereby becomes a source of heat generation. When the reaction is completed and the reaction product contained in the reactor 9 is heated again, the gas absorbed by the reagent is released and then condensed in the evaporator 13.

  According to the present invention, as shown in the drawings, the reactor 9 and the evaporator 13 are arranged in separate compartments 10 and 14, respectively, and are not shown in the drawing, and therefore the control of the micro-controller described below. Under the control of a system of six distribution valves which are interlocked together below, the respective inlets 10a and 14a of the compartments 10 and 14 are in communication with an intake duct 5 which communicates with the outlet 5a of the enclosure 1. The outlets 10b and 14b can be communicated with an outlet duct 7 that communicates with the inlet 7a of the enclosure 1 as well.

  In the accompanying drawings, one end of the intake duct 5 can be connected to the intake ports 10a and 14a described above, and the second end of the intake duct 5 is connected to an outlet 5a formed in the enclosure 1. Similarly, one end of the outlet duct 7 can be connected to the outlets 10 b and 14 b described above, while the other end of the outlet duct 7 is connected to an outlet 7 a made in the enclosure 1.

  Reactor section 10 includes venting means 12 that provide air circulation from its inlet 10a to its outlet 10b, forcing the air into enclosure 1 via outlet duct 7. Similarly, the evaporator compartment 14 includes a venting means 16 that provides air circulation from its inlet 14a to its outlet 14b, forcing the air into the enclosure 1 via the outlet duct 7.

  The reactor section 9 includes an intake valve 17a and an outlet valve 17b. The intake valve 17a and the outlet valve 17b are respectively in an open position (FIG. 2) where the reactor section 10 communicates with the outside, and the reactor section 10 from the outside. It is possible to occupy a closed position (FIG. 3) that is isolated.

  Similarly, the evaporator compartment 14 includes an intake valve 19a and an outlet valve 19b. The intake valve 19a and the outlet valve 19b are respectively in an open position (FIG. 3) where the evaporator compartment communicates with the outside, and the evaporator compartment is external. It is possible to occupy a closed position (FIG. 2) that is isolated from

The system has two reversing valves, namely three positions:
A first position as shown in FIG. 2, wherein the inlet and outlet of the evaporator 13 are each in communication with the enclosure 1;
The second position shown in FIG. 3, where the inlet and outlet of the reactor 9 are each in communication with the enclosure 1;
An intake air in which the valve is in an intermediate position and can occupy the third position shown in FIG. 4, which communicates the inlet and outlet of the reactor 9 and the evaporator 13 with the enclosure 1, respectively. A valve 21a and an outlet valve 21b are also included.

In the example of use of the invention, the product 3 contained in the enclosure 1 is transported internationally. The enclosure must be maintained at a constant temperature _Tc of 5 ° C. and is subjected to various temperature changes during the transport.

  Thus, in the example of the present invention, as shown in FIG. 1, a container equipped with a temperature control device according to the present invention is first transported from its warehouse where the temperature is 15 ° C. (period 1), and the temperature Is dropped into an aircraft cargo compartment that remains at about -20 ° C for 10 hours (period 2). Upon arrival, the containers are placed outdoors at a temperature of 40 ° C. for 4 hours (period 3) and then transferred to the hangar load zone where they remain at a temperature of 25 ° C. for 5 hours (period 4). ). The container is then loaded into the cargo compartment of another aircraft, where its temperature drops to -20 ° C over a period of 5 hours (period 5) and then transported at an external temperature of -30 ° C to the place where it is received. (Period 6).

  Under these conditions, during periods 1, 3 and 4, it is apparent that the enclosure 1 must be cooled and the microcontroller must control the switching valve to the position shown in FIG. Yes, i.e., reversing valves 21a and 21b open the inlet 14a and outlet 14b of the compartment 14 containing the evaporator 13, so that the evaporator communicates with the enclosure to cool the enclosure 1; The valves 19a and 19b are in the open position, and at the same time, the inlet 10a and outlet 10b of the compartment 10 are in communication with the outside in order to remove the heat generated by the reactor 9 during the thermochemical reaction into the atmosphere. Valves 17a and 17b are opened.

  Conversely, during periods 2, 5 and 6, the enclosure 1 must be heated again, and for this purpose the valve is in the position shown in FIG. The reversing valves 21a and 21b open the inlet 10a and outlet 10b of the compartment 10 containing the reactor 9 so that the compartment 10 containing the reactor 9 is in communication with the enclosure to reheat the And 17b are in a closed position with respect to the outside, and at the same time, the valves 19a and 19b are opened so that the evaporator communicates with the outside in order to exclude the cool air generated by the evaporator 13 into the atmosphere.

According to the present invention, the external temperature enclosures - enclosures when fluctuates around definite temperature T _c of Ja 1 - so as to be able to finely adjust the temperature in the Ja, the valve shown in Figure 4 As shown, the hot air and the cold air are placed in the enclosure 1 at the same time. For this purpose, the reversing valves 21a and 21b are brought to an intermediate position, and the intake valves 17a and 19a and the outlet valves 17b and 19b ensure communication between the intake and outlet of both the reactor and the evaporator and the enclosure. To do.

  Of course, any other mode that switches other than valves can be used in accordance with the present invention.

  Accordingly, as shown in FIGS. 2 to 5 a, the adjusting device according to the invention can be attached to the upper part of the enclosure 1. However, as shown in FIG. 5 b, the adjusting device can also be attached to the lower part of the enclosure 1. The housing 22 is therefore mounted above or below the enclosure 1.

  In another embodiment of the invention, the adjusting device can also be arranged between the two enclosures 1 and 1 ', which causes hot air to flow into one of the enclosures (enclosure 1). It offers the advantage that it is possible to send cold air to the other enclosure (enclosure 1 ') at the same time.

Claims (12)

A modular device that can be attached to at least one storage enclosure (1, 1 ′) and automatically adjusts the temperature to a specific setpoint (T _c ), possibly with an evaporator A housing containing a thermochemical system comprising a tank (13) containing a liquefied gas that can be combined with a reaction product contained in a reactor (9) after evaporation according to an exothermic thermochemical reaction 22), and the resulting reaction product can be regenerated while releasing the gas by heating according to a reverse thermochemical reaction, and the reactor (9) of the thermochemical system and The evaporator (13) constitutes a means for heating and cooling the enclosure, respectively. A reactor compartment (10) and an evaporator compartment ( 4) to be arranged, as well, the device is disposed in the housing (22):
The reactor compartment (10) is in communication with only the storage enclosure (1) to heat the storage enclosure (1), while at the same time the evaporator compartment (14) is connected to the outside of the device. Communicate
-In order to cool the storage enclosure (1), the evaporator compartment (14) is in communication only with the storage enclosure (1) and at the same time the reactor compartment (10) is connected to the outside of the device. A modular device, characterized in that it further comprises switching means which can be communicated.   The means according to claim 1, characterized in that it comprises means capable of communicating the reactor compartment (10) and the evaporator compartment (14) simultaneously with the first storage enclosure (1). apparatus.   Intake duct (5) and outlet connectable to the inlet (10a) and outlet (10b) of the reactor compartment (10) and the inlet (14a) and outlet (14b) of the evaporator compartment (14), respectively. Device according to claim 1 or 2, characterized in that it comprises a duct (7).   The inlet duct (5) and the outlet duct (7) are connectable to an outlet (5a) and an inlet (7a) of the first storage enclosure (1), respectively. Item 4. The apparatus according to Item 3.   Said reactor compartment (10) and / or said evaporator compartment (14) comprise means (12, 16) capable of activating the circulation of air flow through said compartment (10, 14) The apparatus according to claim 1.   6. The device according to claim 1, wherein the switching means comprises a valve.   The reactor compartment (10) includes an intake valve (17a) and an outlet valve (17b), and each of the intake valve (17a) and the outlet valve (17b) is connected to the reactor compartment (10). An open position in communication and a closed position in which the reactor compartment (10) is isolated from the outside can be maintained, and the evaporator compartment (14) includes an intake valve (19a) and an outlet valve (19b). Each of the intake valve (19a) and the outlet valve (19b) has an open position where the evaporator section (14) communicates with the outside, and a closed position where the evaporator section (14) is isolated from the outside. The device according to claim 1, wherein the device can be held. The device has two reversing valves, ie three positions:
A first position for communicating the inlet (14a) and the outlet (14b) of the evaporator compartment (14) with the enclosure (1), respectively;
A second position for communicating the inlet (10a) and the outlet (10b) of the reactor compartment (10) with the enclosure (1), respectively;
The valve is in an intermediate position and can hold a third position in which the inlet and outlet of the reactor compartment (10) and the evaporator compartment (14) are in communication with the enclosure (1), respectively; Device according to claim 7, characterized in that it comprises an intake valve (21a) and an outlet valve (21b).   The reactor compartment (10) is formed in communication with the first enclosure (1), and at the same time the evaporator compartment (14) comprises a second enclosure (1). 9. The device according to any one of claims 1 to 8, characterized in that it is formed in communication with ').   10. A device according to any one of the preceding claims, characterized in that it comprises at least a first enclosure (1, 1 ') to which the housing (22) is attached.   11. Device according to claim 10, characterized in that the housing (22) is attached to the upper part of the first storage enclosure (1).   The apparatus includes a second storage enclosure, the reactor compartment (10) is in communication with the first enclosure (1), and at the same time the evaporator compartment (14) is 12. Device according to claim 10 or 11, characterized in that it is in communication with said second enclosure (1 ').

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