WO2013030483A1

WO2013030483A1 - Vehicle for the refrigerated transport of products the energy consumption of which is improved by incorporating a phase-change material into the walls of the vehicle body

Info

Publication number: WO2013030483A1
Application number: PCT/FR2012/051824
Authority: WO
Inventors: Thierry Dubreuil; Mohammed Youbi-Idrissi
Original assignee: L'air Liquide,Societe Anonyme Pour L'etude Et L'exploitation Des Procedes Georges Claude
Priority date: 2011-08-30
Filing date: 2012-08-02
Publication date: 2013-03-07
Also published as: JP2014525560A; FR2979297B1; FR2979297A1; EP2750928A1; US20140216101A1; AU2012300721A1

Abstract

A vehicle for the refrigerated transport of products comprising at least one products storage chamber, characterized in that: - one or more panels (4) made from a material of so-called "phase-change" type have been incorporated into the structure of all or part of the walls of at least one of the storage chambers of the lorry; - the phase-change material has a melting point that is just a few degrees higher than the target datum temperature for the chamber in question, preferably 2 to 10°C higher than said datum temperature and more preferably still 3 to 5°C higher than said datum temperature.

Description

VEHICLE FOR REFRIGERATED TRANSPORT OF PRODUCTS WITH ENERGY CONSUMPTION ENHANCED BY

THE INCORPORATION OF A MATERIAL WITH A CHANGE OF

PHASE IN THE WALLS OF THE CAISSE

The present invention relates to the field of transport and distribution of thermosensitive products, such as pharmaceuticals and foodstuffs. Controlled and controlled temperature transport has become a major challenge in the context of the respect of the cold chain, which is essential for maintaining the quality and viability of organic products, whether they be foodstuffs or medicines, vaccines, bio -Samples, etc. Typically it will be recalled that perishable food products are transported fresh or frozen (positive or negative temperature), while drugs and vaccines are transported fresh (positive temperature). The transport typically takes place between the place of production, the places of storage or distribution, and the places of sale and / or consumption. Fresh or frozen food is transported by refrigerated truck. This transport relies mainly on "mechanical" groups of cold generation. It is also possible to use so-called "cryogenic" solutions based on the use of liquid nitrogen or CO ₂ as cold sources for maintaining positive (fresh) or negative (frozen) cold.

The advantages of cryogenic solutions, whether it is so-called "direct" injections into the interior of the storage room or products (spray) or so-called "indirect" injections (where the cryogenic fluid is then conveyed from a cryogenic tank on board the refrigerated truck (usually below the truck) to one or more heat exchangers located inside the cold room or chambers of the truck) are well indexed, but see their market penetration curbed by the associated economic cost.

And one of the items heavily influencing the economic balance is of course the amount of cryogen (nitrogen or CO ₂ ) required for the production of cold at the desired temperatures.

The physical analysis of the heat exchange mechanisms clearly shows that the thermal inertia of the walls of the storage chamber or chambers represents an important part of the energy balance. It alone could, in certain configurations, be responsible for 50% of global cryogen consumption.

The present invention then seeks to provide a solution for recovering at least part of the cold given to the walls for later reuse during the operational phase of the truck.

It is known that currently, in refrigerated trucks, the insulating walls used today are most commonly made of polyurethane with a plastic coating on the outside and a conductive material on the inside ("cold" side in contact with the bedroom). The cold setting of this structure consumes a lot of time and primary energy.

As will be seen in more detail in the following, the present invention proposes a new structure of walls, which can be summarized as follows:

- It incorporates in the structure of all or part of the walls of at least one of the storage rooms of the truck, one or more panels made of a material "less energy consuming", this material is of the type called "phase change"; this incorporation is preferably done in all or part of the wall half located on the side of the cold source (storage chamber side, which includes the injectors in a "direct" injection, or the exchangers in an "indirect"injection);

- By way of illustration, according to an exemplary implementation of the invention, the following succession of layers starting from the inside of the box: a conductive layer, a layer of phase-change material, a layer of polyurethane, and a plastic layer, the conductive layer on the inside of the body acting as a thermal transmission plate to the phase change material;

the phase-change material is chosen so as to obtain a suitable melting point according to the type of application targeted (transport in fresh, frozen) and the desired temperature range (very specific temperature ranges, for example for certain products biological). For reasons which will be explained better below, a phase-change material whose melting temperature is only a few degrees higher than the target temperature referred to in the chamber in question is preferentially used according to the invention. 2 to 10 ° C above the set temperature and more preferably from 3 to 5 ° C.

As an example of the instructions traditionally practiced in this transport industry, we can cite the example of a set point of 0 to 4 ° C for the transport of fresh products, while we meet instructions of - 20 ° C for the transport of frozen products, these two instructions can be implemented in two adjacent rooms of the same truck.

By way of example, a material with a melting temperature of + 8 ° C. for fresh transport and with a melting point of -10 ° C. for frozen food is chosen according to the invention.

These materials can be chosen in the range of organic materials including waxes, oils, fatty acids and polyglycols or in the range of capsules filled with salt hydrates.

The advantageous nature of the presence of such a material in the wall of the body is related to its ability to store cold at the time of setting in cold of the truck (at the start, or after a door opening ...), then to restore it when the temperature of the body is higher than the melting temperature.

The latent heat of melting / solidification then makes it possible to save a large amount of primary energy (nitrogen or CO2 in the case of cryogenic solutions) and thus reduce their consumption.

The present invention thus relates to a refrigerated product transport vehicle, comprising at least one product storage chamber, of the type in which the cold production system implemented by the vehicle is cryogenic, by direct or indirect injection of a fluid. cryogenic in said at least one storage chamber, and characterized in that:

- The structure of all or part of the walls of at least one of the storage chambers of the truck, one or more panels made of a material called "phase change" type;

the phase-change material has a melting temperature which is only a few degrees higher than the target temperature referred to in the chamber in question, preferably from 2 to 10 ° C. higher than said setpoint, and still more preferably from 3 to 5 ° C higher than the said set point.

According to one of the preferred embodiments of the invention, the phase-change material is incorporated in all or part of the wall half located on the side of the cold source (storage chamber side), and even more preferably in all or part of the wall third located on the side of the cold source.

The appended FIG. 1 then illustrates in section, not its two views a) and b): in a): a wall structure that is encountered in certain current trucks, with the succession, starting from the inside of the checkout, a conductive layer 1, a polyurethane layer 2, and a plastic layer 3;

- In b) an example of implementation of the invention, which is incorporated in the previous structure, a layer 4 of phase change material, it is noted that this layer 4 is incorporated substantially in the half wall which is the side of the room.

Let us explain in the following an example of behavior of the wall during an operational phase of the truck.

For a refrigerated truck intended for the transport of fresh products, the start of the cold production system (whether direct or indirect injection of a cryogenic fluid) makes it possible to lower the temperature of the air internal to the chamber to the setpoint, then maintain this temperature by system regulation. In a manner well known to those skilled in the art, the existing solutions for controlling the temperature of the air internal to the body storing the products transported, use control algorithms of the opening / closing of the valves supplying the injectors or internal exchangers at the cryogenic box.

After each delivery of one or more pallets, the doors being open on the outside air, the temperature of the air in the truck rises and the system of production of the cold must provide the refrigerating power necessary to find the set temperature also as quickly as possible to respect the cold chain.

The time required to reach the set point at first start and after each door opening depends on several parameters, mainly the maximum cooling capacity that can be provided by the cold production system, but also the indoor / outdoor temperature difference. and thermo-physical properties (including conductivity) of the materials composing the walls of the truck.

Although the air reaches its set temperature after a time defined by the operating parameters mentioned above, the walls of the truck continue to absorb energy because their thermal inertia is much more great than air. Consequently, they do not reach equilibrium until after a few hours of the temperature drop time inside the truck (this time is called in this industry "pull down"). In the case of a refrigerated truck according to the invention, consisting wholly or partially of walls containing phase change materials, when the air temperature is lowered when starting or after a door opening, the temperature in the the walls also drop, especially in the layer containing the phase change material which will see its temperature drop until it reaches its solidification temperature. We then start the energy storage phase in this material which will gradually solidify.

More specifically, at the start of a tour or after an extended door opening, it will bring cryogen, to lower the internal temperature to the storage room products at a required setpoint (for example since 20-25 ° C up to + 4 ° C for fresh products), whether direct injection (spray) or indirect injection (exchangers). Following this supply of cryogen, the temperature in the walls will drop, especially in the layer containing the phase-change material which will see its temperature drop until it reaches its solidification temperature.

We then start the energy storage phase in this material which will gradually solidify.

Due to the material selection carried out, the energy storage in the material will then start before the internal air temperature setpoint has been reached, and the partial or complete solidification of the material before the set the air internal to the chamber has been reached will depend on different parameters, mainly its thermo-physical properties (conductivity, heat mass), and the amount of material used (the mass), but one preferentially attaches to selecting the right amount of suitable material for the material to be completely or almost completely solidified when the temperature reaches the internal set point at the body.

When a significant door opening occurs later during the tour, and the resulting internal air temperature rise, the return to the set temperature of the inside of the body will be faster because the material with change of phase will restore some of the stored energy to the air, resulting in energy savings.

So at each moment of the journey of the vehicle:

- if the temperature inside the chamber exceeds the required setpoint by a very small amount (eg 1 K), the material will give off a little energy (sensible heat variation), helping the air to return to its temperature , it can then be used as buffer to better smooth the temperature variation.

- If the temperature inside the chamber increases by several degrees following a door opening (s) of a few minutes for example, the material gives up a good deal of its energy up to a partial melting (variation of its latent heat ) and facilitates the rapid return of air to its set temperature, thus requiring less input of the primary cryogen: the temperature control system present on such vehicles, by the control of the opening / closing of the valves supplying injectors or internal exchangers to the cryogenic body according to an internal temperature take into account (benefit) of course the energy input from the phase change material panels.

And the choice in this respect of a phase change material with a melting temperature slightly higher than the desired air temperature is very advantageous since, on the other hand, a material with a melting temperature below the set temperature would continue to store. energy during the maintenance phase (a useless process), and that, moreover, with each return at the set temperature, it would continue to consume energy since naturally it will tend to want to solidify.

Claims

claims

1. Product refrigerated transport vehicle comprising at least one product storage chamber, of the type where the cold production system implemented by the vehicle is cryogenic, by direct or indirect injection of a cryogenic fluid into the at least one a storage chamber, characterized in that:

- The structure of all or part of the walls of at least one of the storage chambers of the truck, one or more panels (4) made of a material called "phase change" type;

2. Vehicle according to claim 1, characterized in that the phase change material is incorporated in all or part of the wall half located on the side of the cold source (storage chamber side), and even more preferably in all or part of the wall third located on the side of the cold source.