FR2967243A1 - REFRIGERANT DEVICE WITH PELTIER EFFECT - Google Patents

Abstract

The invention relates to a refrigerating system, adapted to be removably positioned on a duct in which vapors to be condensed circulate, the said refrigerating system comprising: • a thermoelectric device (10, 11, 15) having a recess opening into which insert the conduit to be cooled, an internal surface of the recess forming a cold surface of the thermoelectric device and • a control module (47) for supplying the thermoelectric device with an electric current depending on a desired temperature on the cold surface of the device thermoelectric. Application to the condensation of vapors in reflux heating operations.

Description

The invention relates to a refrigerant system, adapted to be removably positioned on a conduit in which vapors to be condensed circulate.

Such a refrigerant system can in particular be used in the laboratory to condense vapors in reflux heating operations to accelerate or allow a chemical reaction without loss of reagents or products, and to limit solvent emissions. The so-called reflux heating operation is a great classic of laboratory manipulations in chemistry, biology or medical analysis both in the educational and professional fields. The actual embodiment of a reflux heating operation requires a step of condensation of the vapors produced by the heating block, in order to avoid any effect of concentration of the dissolved molecules in the heated liquid and to limit the solvent emissions. The condensation function is conventionally provided by a refrigerant system attached to an outlet of the heating block generally consisting of a reaction vessel (for example a glass-balloon) associated with a heating device. The refrigerant system is usually a double-walled tube fed, usually in open loop, by water from the drinking water network (tap water).

For volatile compounds, the temperature of the tap water is often too high to provide effective condensation and a cryostat is needed to ensure a temperature of the water flowing in the lower double wall. These two options (open tap water system or closed loop water circuit with cryostat cooling) lead to refrigeration devices that either consume a lot of water for the first case, or are complex and expensive in equipment. for the second case (need to invest in a cryostat, a circulation pump ...). Moreover, these two options present the difficulties associated with the use of a liquid in circulation (risk of leakage, development of algae or bacterial contamination, fouling, etc.) Description of the invention The invention proposes a new refrigerant system, particularly well suited for carrying out a reflux operation, and not having all or some of the disadvantages of known refrigerating devices. Thus, the invention proposes a refrigerant system, adapted to be removably positioned on a conduit in which vapors to be condensed circulate, for example vapors from a laboratory heating block. The refrigerant system comprises: - a thermoelectric device having a through opening in which can be inserted the conduit to be cooled, an inner surface of the recess forming a cold surface of the thermoelectric device, and - a control module for providing the thermoelectric device a electric current function of a desired temperature on the cold surface of the thermoelectric device. The thermoelectric device is a device adapted to produce from an electric current a temperature difference between a cold surface and a hot surface of the device. Thus, from the current supplied, the system according to the invention will cool the inner surface of the recess and therefore any conduit positioned inside the recess. In the cooling system according to the invention, a vapor evacuation duct can easily be positioned inside the recess. The system according to the invention can thus be easily used on a tube, glass or other, fixed on an outlet of a laboratory reaction vessel for example. When they climb into the duct and arrive at the refrigeration system, the vapors rising from the reaction vessel condense and fall back into the vessel. The system according to the invention does not consume water and only a small amount of electrical energy. In addition, to cool a small conduit, for example a glass tube with a diameter of 1 to 3 cm, a thermoelectric device of small power, of the order of 10 to 30 Watt is sufficient. Since such a thermoelectric device is small, the system according to the invention is of small size and of reduced weight also, so that the system is portable and can very easily be moved from one installation to another, from one place to another. In one embodiment, the thermoelectric device comprises a Peltier module in the form of a hollow tube, an inner surface of the hollow tube forming a cold surface of the Peltier module. In this case, the particular shape of the Peltier module allows it to easily adapt to the vapor exhaust duct and provides maximum efficiency of the refrigerant system. In another embodiment, the thermoelectric device comprises N Peltier modules each having a substantially flat cold face, the N Peltier modules being associated to form together a hollow tube having a recess with a cold internal surface. The number of Peltier modules is chosen according to the shape of the section of the duct containing the vapors, for example 4 modules for a duct of square section, 6 or more modules for a duct of circular section, etc. The realization of the thermoelectric device is thus optimized so that the conduit marries at best the shape of the recess. In yet another embodiment, the thermoelectric device comprises: a ring-shaped connecting member having a hollow opening into which the duct to be cooled can be inserted; N Peltier modules fixed on an outer surface of the ring. The contact member makes it possible to interface the pipe to be cooled and the Peltier module (s). The contact member is made of a good thermal conductive material, for example aluminum. It is pierced with a recess opening (hence its ring shape) whose inner surface is adapted to that of the duct to cool. It allows for an inexpensive cooling system by using flat Peltier modules, which are widely available at lower cost in the trade. In one embodiment, the thermoelectric device is made in two parts which, associated by a hinge means, for example a hinge, and movable between a closed position where the two parts together have a general shape having a opening opening in which can be positioned the duct to cool, and an open position allowing the passage of the duct to cool. The refrigerant system can thus be easily installed on the tube to be cooled, even in difficult conditions, for example if the tube has larger end sections than the sections of the body of the tube to be cooled or if the tube ends are difficult to access.

If necessary, the system according to the invention may also comprise a device for discharging heat in the vicinity of a hot surface of the thermoelectric device, for example a radiator, possibly ventilated. If, in the cooling system, the thermoelectric device comprises N Peltier modules each having a cold surface, the heat dissipating device may comprise N radiators each having a shape adapted to be in contact with the hot surface of a Peltier module . In a variant also, the cooling system may comprise several thermoelectric devices, positioned next to each other so that the assembly has the general shape of a hollow tube adapted to be positioned along the conduit containing the vapors to be condensed . In a further variant, the system according to the invention may comprise several associated thermoelectric devices so that the recesses of all the thermoelectric devices are in the extension of one another.

It is thus possible to cool the duct over a longer length and / or at a lower temperature and / or to apply a temperature gradient along the duct. The control device provides an electric current depending on the desired temperature and / or the number of thermoelectric devices and / or the number of Peltier modules per thermoelectric device, as will be seen better below. For example, if the thermoelectric device comprises N Peltier modules, the control module can be adapted to provide an electric current to a number of Peltier modules depending on a desired temperature on the inner surface of the thermoelectric device. In another example of a refrigerant system comprising a plurality of thermoelectric devices, the control device may be adapted to provide each thermoelectric device with an electric current depending on a desired temperature on the inner surface of said thermoelectric device, the electric current supplied being able to be different from one thermoelectric device to another. Finally, in a preferred version of the invention, the control module and the thermoelectric device or devices are grouped together in one and the same housing or in two half-housings associated by means of articulation to form a housing, in which the housing comprises a through recess whose shape is adapted to the shape of the conduit, and wherein the housing is adapted so that the inner surface of the thermoelectric device comes into contact with the conduit when the cooling device is positioned on the conduit.

Brief description of the figures The invention will be better understood, and other features and advantages of the invention will become apparent in light of the following description of embodiments of refrigerant devices according to the invention. These examples are given in a non-limiting manner. The description is to be read in conjunction with the accompanying drawings in which Figures 1 to 8 show elements that can be used for the implementation of a system according to the invention. DESCRIPTION OF AN EMBODIMENT OF THE INVENTION The essential elements of the invention are Peltier modules that transform an electric current into a temperature difference. Each module includes a cold surface and a hot surface, and transfers available energy in the vicinity of the cold surface to the hot surface. Under optimum performance conditions, such a Peltier module consumes a current of about 2 amperes at a voltage of 12 V, to evacuate an energy of the order of 0.5 to 1 Joule. A refrigerant system according to the invention is adapted to be removably positioned on a duct in which vapors circulate, for example an outlet tube 41 of a liquid heating container (not shown), such as a glass- ball. The refrigerant system comprises: - a hollow tube-shaped thermoelectric device 10, 11, 15 comprising a cold internal surface whose shape is adapted to a shape of the conduit and - a control module 47 for supplying an electric current to the thermoelectric device.

Figures 1 to 3 show different modes of association of Peltier modules to form the thermoelectric device of a cooling system according to the invention. In the example of FIG. 1, the thermoelectric device comprises a single Peltier module in the form of a hollow tube 10 whose inner surface corresponds to the cold face of the Peltier module. In the example of FIG. 2, the thermoelectric device 11 comprises N = 4 Peltier modules 12 each having a cold face and a hot face. The Peltier modules are associated to form together a hollow tube whose cold inner surface is adapted to a square section conduit. In the example of FIG. 3, the thermoelectric device 15 comprises N = 10 to 20 associated Peltier modules 16 to form a hollow tube of which a section comprises N sides. The larger N is, the more the section of the hollow tube approaches a circular shape. The Peltier modules can be associated with each other by an adhesive tape for example, or by means of a more rigid structure. FIG. 4 shows a thermoelectric device comprising N = 2 Peltier modules 43, 44 associated by means of a ring-shaped connecting member 42. In the example shown, the ring has a substantially parallelepipedal external shape and is pierced with an opening opening whose wall forms the inner surface of the thermoelectric device. The ring is made of aluminum, a good thermal conductive material. The N = 2 Peltier modules are flat and are fixed on two opposite sides of the ring parallel to a longitudinal axis of the recess. In a variant, two other Peltier modules can be added on the other two sides of the ring. In a variant also, the outer sides of the ring not covered by a Peltier module are covered with a thermal insulating coating. Thus the Peltier modules only cool the ring and dissipate only the energy provided on the wall of the recess by the pipe to be cooled. In the example of Figure 4 also, a ventilated radiator 45, 46 is fixed on the hot surface of each of the Peltier modules to evacuate heat to the outside. Depending on the heat to be dissipated, the ventilated radiator (s) may be replaced by any other suitable means for evacuating the heat, for example by a simple radiator. In the example of FIG. 4 again, the control module 47 supplies a current to a number of Peltier modules according to the desired temperature. Thus, the greater the number of Peltier modules supplied with current, the higher the temperature can be lowered on the cold surface of the thermoelectric device or devices. Preferably, the current supplied to each Peltier module is chosen so that said module operates at its maximum efficiency.

As an indication, the two Peltier modules of 40 mm by 40 mm, supplied in series by a current of 2 amperes at 12 volts, make it possible to obtain a temperature of the order of 0 ° C. on their cold side, when the module is at room temperature. Unfortunately, the small size of the Peltier modules makes it possible to produce a refrigeration system of small size, of dimensions of the order of ten centimeters, and of reduced weight, of the order of a few hundred grams. The system can thus be easily installed on any conduit, and be easily transportable from one conduit to another and from one place to another.

In the example of Figure 5, the system comprises two thermoelectric devices 51, 52 mechanically associated so as to form together a opening opening. The control device is here adapted to provide each thermoelectric device with a different current so that the cold surface of the thermoelectric devices is different. This makes it possible to obtain a temperature gradient along the hollow tube. Finally, a refrigeration system according to the invention comprises a housing in which are grouped together the control module and the thermoelectric device or devices. The housing can be made in a single portion 61 (Figure 6) or in two parts 71, 72 assembled by a hinge means such as a hinge 73 (Figure 7). The housing comprises an opening opening whose shape is adapted to the shape of the conduit. And the housing is adapted for the inner surface of the thermoelectric device (s) to come into contact with the conduit when the refrigerant system is positioned on the conduit. The electrical energy necessary for the operation of the cooling system can be supplied to the control module either by a battery or by an electrical energy distribution network, by means of a current transformer if necessary.

Claims (10)

REVENDICATIONS1. A refrigerant system adapted to be releasably positioned on a conduit in which vapors to be condensed circulate, said refrigerant system comprising: - a thermoelectric device (10, 11, 15) having a through recess in which can be inserted the conduit to cooling, an inner surface of the recess forming a cold surface of the thermoelectric device and - a control module (47) for providing the thermoelectric device with an electric current depending on a desired temperature on the cold surface of the thermoelectric device. 2. Refrigerant system according to claim 1, wherein the thermoelectric device comprises a Peltier module in the form of a hollow tube (10), an inner surface of the hollow tube being a cold surface of the Peltier module. 3. Refrigerant system according to claim 1, wherein the thermoelectric device (11, 15) comprises N Peltier modules (12, 16) having a substantially flat cold surface, the N Peltier modules being associated to form together a hollow tube having a recess with a cold internal surface. 4. Refrigerant system according to claim 1 wherein the thermoelectric device comprises: - a ring-shaped connecting member (42) having a recess in which can be inserted into the conduit to be cooled, - N Peltier modules (43, 44 ) fixed on an outer surface of the ring. 5. Refrigerant system according to one of the preceding claims, wherein the thermoelectric device is made in two parts associated by a hinge means, for example a hinge, and movable between a closed position where the two parts together have a general shape having a opening opening in which can be positioned the pipe to be cooled, and an open position allowing the passage of the pipe to be cooled. 6. Refrigerant system according to one of the preceding claims also comprising a device (45, 46) for discharging heat in the vicinity of a hot surface of the thermoelectric device. 7. Refrigerant system according to claim 6, wherein: the thermoelectric device comprises N Peltier modules each having a cold surface, the heat dissipating device comprises N radiators (45, 46) each having a shape adapted to be in contact with the hot surface of a Peltier module. 8. Refrigerant system according to the preceding claim, wherein the thermoelectric device comprises N Peltier modules and wherein the control module is adapted to provide an electric current to a number of Peltier modules function of a desired temperature on the inner surface of the device thermoelectric. 9. Refrigerant system according to one of claims 7 or 8, comprising a plurality of thermoelectric devices, and wherein the control device is adapted to provide each thermoelectric device with an electric current function of a desired temperature on the inner surface of said device. thermoelectric, the electric current supplied may be different from one thermoelectric device to another. 10. Refrigerant system according to one of the preceding claims, wherein the control module and the thermoelectric device or devices are grouped in the same housing, or in two half-housings associated by a hinge means to form a housing, in wherein the housing comprises a through recess whose shape is adapted to the shape of the duct to be cooled, and wherein the housing is adapted so that the inner surface of the thermoelectric device surrounds the duct to be cooled when the refrigerant system is positioned on the duct .