ITMI930302A1 - PELTIER EFFECT REFRIGERATING SYSTEM - Google Patents

Description

DESCRIPTION

The present invention relates to a Peltier effect refrigeration system.

The Peltier effect refrigeration system is, as known, based on the principle of absorption and generation of thermal power at the junctions of a thermoelectric circuit crossed by electric current. The thermoelectric circuit? said thermoelement and comprises two branches of suitable material, for example semiconductors or semimetals, and two junctions, one hot and one cold.

Normally, in practice, a so-called Peltier effect thermoelectric module is used, comprising two parallel and opposite plates, between which? interposed a set of thermoelements, so that the hot junctions of the thermoelements are in contact with one of the two plates and the cold junctions of these thermoelements are in contact with the other of the two plates. The cold plate, that is the one in contact with the cold junction, constitutes the cold source of the refrigerating system.

One of the defects of this refrigeration system? the low performance that limits its applications.

Another drawback? that, in certain cases in which this refrigeration system must operate in certain external environmental conditions of high temperature,? it is necessary to deactivate the thermoelectric module, or to remove the power supply from it, in order to avoid malfunctions or damage to the module itself. In this way, however, the refrigeration system fails to function with imaginable consequences.

An additional drawback? represented by the relatively long time required for this refrigeration system to reach full capacity.

Purpose of the present invention? to overcome the aforementioned drawbacks.

This object is achieved by means of a refrigeration system comprising at least one Peltier effect thermoelectric module having two plates between which? interposed a set of electrically powered thermoelements cos? to heat one of the two plates and to cool the other of the two plates, the cold plate constituting the cold source of the refrigerating system, characterized by the fact of providing a cooling liquid by means of which heat is removed from the hot plate.

To better understand the invention, a description of a non-limiting exemplary embodiment thereof is reported below, illustrated in the attached drawings in which:

Fig. 1 schematically shows a Peltier effect refrigeration system according to the invention;

Figure 2 schematically shows a variant of the refrigerating system of Figure 1;

Fig. 3 is a perspective view of an application of the refrigerating system of Fig.

The refrigerating system of Fig. 1 comprises a Peltier effect thermoelectric module 10 of the type described in the introduction.

Module 10 comprises two parallel and opposite plates 11 and 12, between which? interposed in a set of thermoelements 13.

By electrically powering the set of thermoelements 13, the plate 11 heats up and the plate 12 cools. Plate 12 constitutes cos? the cold source of the refrigeration system.

The hot plate 11 forms a wall of a chamber 14 in which a cooling liquid is passed.

Room 14? connected in a closed circuit to an external pipe 15 in which the cooling liquid runs. The connection between chamber 14 and pipe 15? carried out through two holes 16,17, respectively of inlet and outlet, obtained in the chamber itself: one end? of pipe 15? connected to hole 16, while the other end? of pipe 15? connected to hole 17.

Along the pipe 15? arranged a pump 18 driven by an electric motor 28, a heat exchanger 19 and a tank 20. At the heat exchanger 19? arranged a fan 21 driven by an electric motor 29.

In contact with the cold plate 12? placed a plate 22 with fins 23.

Plate 22? placed inside the room to be cooled, while the pipe 15? placed outside this environment. In fig. 1? also illustrated is a wall 24 which divides the environment to be cooled from the outside; in that wall 24? built-in chamber 14.

In room 14? placed a temperature sensor 25, and likewise in the room to be cooled? placed another temperature sensor 26.

The refrigeration system of fig. 1 also includes a? Unit? command and control electronics 27, with microprocessors, connected to the thermoelectric module 10, to the electric motors 28 and 29 respectively of the pump 18 and the fan 21, and to the temperature sensors 25 and 26.

Operationally, the unit? 27 command and control commands the power supply of the thermoelectric module 10 and the activation of the electric motors 28 and 29.

The power supply of the thermoelectric module 10 causes, as already? said, the heating of the plate 11 and the cooling of the plate 12.

The plate 22, in contact with the cold plate 12, provides for the refrigeration of the environment to be cooled by heat exchange with the latter; the fins 23 of the plate 22 increase this heat exchange.

The activation of the electric motor 28 activates the pump 18 which circulates in a closed circuit the coolant liquid along the chamber 14 and the pipe 15 in the direction indicated by the arrows. In particular, the coolant flows into the chamber 14, coming from the tank 20, through the hole 16 and in this chamber it removes heat from the hot plate 11 which constitutes a wall of the chamber itself; the coolant then flows from the chamber 14 through the hole 17 and passes inside the heat exchanger 19 where it transfers the heat removed from the hot plate 11 to the outside air; from the heat exchanger 19 the coolant returns to the tank 20 and the cycle begins again.

The activation of the electric motor 29 activates the fan 21 which causes a forced movement of the external air on the external walls of the heat exchanger 19. to increase the efficiency of the heat exchange.

With the continuous removal of heat from the hot plate 11 by the coolant liquid, one has the effect of obtaining and maintaining low temperatures on the cold plate 12. to have a high performance refrigeration system.

Furthermore, this continuous removal of heat avoids overheating of the hot plate 11 in external environmental conditions of high temperature, and therefore does not oblige to interrupt the electrical supply of the thermoelectric module, but allows the refrigeration system to always perform its function.

Finally, this continuous removal of heat quickly brings the refrigeration system up to speed.

The unit? 27 command and control control, by means of thermostats 25 and 26, respectively, the temperature of the refrigerant liquid and of the environment to be cooled so? to be able to fine-tune the cooling of the environment to be cooled and to maintain the latter at the desired temperature, by suitably acting on the power supply of the thermoelectric module 10 and on the activation of the electric motors 28 and 29 of the pump 18 and of the fan 21 respectively. The unit? 27 can for example, vary, at par? power supply voltage, the current supplied to the thermoelectric module 10. The unit? 27 can furthermore, stop the pump 18 and the fan 21 if not? momentarily it is necessary to remove heat from the hot plate 11 to maintain the correct temperature in the room to be cooled. By equipping the pump 18 and the fan 21 with electric motors at speed? variable, the unit? 27 can adjust the speed? of these motors in order to optimize the removal of heat from the hot plate 11, thus optimizing? the efficiency of the refrigeration system.

In fig. 2 the removal of heat from the hot plate 11 takes place as in fig. in a closed circuit with the same characteristics and modalities? of operation views for the coolant.

In particular, do you have a room 14? whose wall? constituted by the cold plate 12, a pipe 15? connected, at the ends, respectively to a hole 16? of entry and to a hole 17? outlet obtained in chamber 14 ?, a pump 18? driven by an electric motor 28 ', arranged along the pipe 15?, and a heat exchanger 19? arranged along the pipe 15? downstream of pump 18? and placed in the room to be cooled; at the heat exchanger 19 '? placed a fan 21? driven by an electric motor 29 ?.

It should be noted that both the circuit relating to the refrigerant liquid and the circuit relating to the heat exchange liquid do not have the tank, present in the circuit of fig. Such a tank can? be put in both circuits if you fear leaks of the respective liquids.

Also in the refrigeration system of fig. 2? present a unit? command and control electronics, with microprocessors, indicated with 30, connected to the thermoelectronic module. 10, to electric motors 28,29,28? , 29 ?, and to two temperature sensors 31 and 32, the first of which placed in an environment to which the refrigerant liquid gives off heat and the second of which placed in the environment to be refrigerated.

In the refrigerating system of fig. 2, the refrigerant liquid removes heat from the hot plate 11 as mentioned above, as seen in the refrigerating system of fig. 1. As regards the cooling of the environment to be cooled, the heat exchange liquid is circulated by the pump 18? in closed circuit in the chamber 14 'and in the pipe 15', cos? to cool in contact with the plate 12 when it flows into the chamber 14? and so? to absorb heat when it flows into the heat exchanger 19? cooling the environment to be cooled; the fan 21? creates a forced movement of the ambient air to be cooled on the external walls of the heat exchanger 19? cos? to increase the efficiency of the heat exchange.

There are therefore all the advantages of removing the heat from the hot plate 11 by the coolant liquid seen in the refrigerating system of fig. there is a more effective cooling of the environment to be cooled.

The unit? 30 of command and control provides to command the power supply of the thermoelectric module 10 and the activation of the electric motors 28, 29,28 ', 29 ?, and thanks to the thermostats 31 and 32 it controls the temperatures of the hot and cold parts of the refrigeration system cos? to provide, by acting appropriately on the thermoelectric module and on the aforementioned electric motors, for the optimal functioning of this refrigeration system.

It should be noted that both the refrigeration system of fig. 1 and that of fig. 2 are structurally and functionally simple and of relatively limited overall dimensions.

Variations and / or additions to what has been described and illustrated above can obviously be envisaged.

Can, for example, be expected more? thermoelectric modules, thermally arranged in parallel, for example side by side, and electrically connected in series or in parallel, so? to be able to increase the capacity? system refrigeration. For the same purpose you can? also provide for a set of thermoelectric modules thermally arranged in series, or in which the hot plate of one? in thermal contact with the cold plate of the other, and electrically connected in series or in parallel; this set of thermoelectric modules will present? a hot external face, relative to the hot plate of one of the two external thermoelectric modules of the whole, from which it will come? removed heat by means of the coolant, and a cold external face, relative to the cold plate of the other of the two external thermoelectric modules of the whole, which will constitute? the source of cold. In general you can? predict a multiplicity? of thermoelectric modules thermally coupled to each other in series and / or in parallel; these thermoelectric modules can then be electrically connected to each other in series and / or in parallel; the thermoelectric modules can form one or more? cold springs and one or more? hot springs, and heat is removed from the latter by means of a coolant.

The refrigerant liquid circuit with which heat is removed from the hot source and its various elements could also be different from those described above and illustrated in Figs.1,2, even if the latter are surprisingly simple and effective. The hot plate can? also not to form the wall of the chamber, but to be in thermal contact with a wall of the chamber itself, even if the solution described and illustrated is optimal for an effective heat exchange.

Similar considerations apply to the circuit of the heat exchange liquid with the cold plate, in relation to the refrigerating system of fig. 2.

The coolant liquid and the aforesaid heat exchange liquid can be of any type capable of effectively performing the specific function; the heat exchange liquid must obviously not freeze at working temperatures.

The heat exchangers can also not be cooled by a fan, however? there? obviously involves a significant decrease in the efficiency of the heat exchange.

The finned plate of heat exchange can? be replaced with a functionally equivalent element.

Pu? be provided for any number of temperature sensors to control the points considered more? appropriate of the hot part and the cold part of the refrigeration system as well as? of the environments in which the various parts of the refrigeration system are located.

In a simplified version, but functionally inferior, you can? delete the unit? command and control electronics and temperature sensors, using in their place thermal switches that operate appropriately on the components of the refrigeration system.

The refrigeration systems described and illustrated, with any variants and / or additions to which yes? mentioned above, they can find application in any case in which it is necessary to cool delimited environments and masses in general, and it is necessary to keep them at temperatures lower than those of the external environment.

For example, such refrigeration systems can be applied to refrigerators, freezers, freezers, and the like. In fig. 3? precisely the application of the refrigeration system of fig.l to a refrigerator is shown: in this figure? partially illustrated in line and point a cabinet 40 of the refrigerator, on a rear wall of which? the finned plate 22 which distributes the cold in the cabinet is mounted on the top and inside; the coolant circuit? placed outside the wardrobe. Obviously the refrigerator can? also use the refrigeration system of fig. 2.

These refrigeration systems can also be applied to air conditioners and the like. For example, they can find an advantageous application in air conditioners for motor vehicles, where their limited space considerably facilitates their placement.

Claims (21)

CLAIMS 1. Refrigerating system comprising at least one Peltier effect thermoelectric module (10) having two plates (11,12) between which? interposed a set of thermoelements (13) electrically powered cos? to heat one (11) of the two plates and to cool the other (12) of the two plates, the cold plate (12) constituting the cold source of the refrigerating system, characterized in that it provides a cooling liquid by means of which heat is removed from the hot plate (11). 2. Refrigerating system according to claim 1, in which said cooling liquid flows, according to a closed circuit, in a chamber (14) in which the heat exchange takes place with said hot plate (11) and in a pipe (15), connected to the chamber (14), which brings the coolant to release heat to the outside. 3. Refrigerating system according to claim 2, wherein said hot plate (11) forms a wall of said chamber (14). 4. Refrigerating system according to claim 2, wherein along said pipe (15)? a pump (18) is arranged which causes the cooling liquid to flow in a closed circuit along the chamber (14) and the pipe (15), and in which along said pipe (15)? also disposed a heat exchanger (19) in which the heat transfer from the cooling liquid to the outside takes place. 5. Refrigerating system according to claim 4, wherein at said heat exchanger (19)? a fan (21) is arranged which creates a forced movement of the external air on the external walls of the heat exchanger (19). 6. Refrigerating system according to claim 2, wherein along said pipe (15)? arranged a tank (20) which receives the coolant. 7. Refrigerating system according to claim 1., wherein in contact with said cold plate (12)? a finned plate (22) for heat exchange with the environment to be cooled is arranged. 8. Refrigerating system according to claim 1, wherein? a heat exchange liquid is provided which comes into thermal contact with said cold plate (12), cooling, and then absorbs heat from the environment to be cooled. 9. Refrigerating system according to claim 8, in which said heat exchange liquid flows, according to a closed circuit, in a chamber (14?) In which the heat exchange takes place with said cold plate (12) and in a pipe (15 * ) connected to the chamber (14?) which brings the heat exchange liquid to absorb heat from the environment to be cooled. 10. Refrigerating system according to claim 9, wherein said cold plate (12) forms a wall of said chamber (14 *). 11. Refrigerating system according to claim 9, wherein along said pipe (15?)? a pump (18?) is arranged which makes the heat exchange liquid flow in a closed circuit along the chamber (14?) and the pipe (15?), and in which along said pipe (15?)? also disposed a heat exchanger (19?) in which the heat is absorbed from the environment to be cooled to the heat exchange liquid. 12. Refrigerating system according to claim 11, wherein at said heat exchanger (19 ')? a fan (21 *) is arranged which creates a forced movement of the ambient air to be cooled on the external walls of the heat exchanger (19?). 13. Refrigerating system according to claim 9, wherein along said pipe (15?)? arranged a tank which receives the heat exchange liquid. 14. Refrigerating system according to claim 1, wherein? expected a multiplicity? of thermoelectric modules (10) thermally coupled to each other in series and / or in parallel. Cooling system according to claim 14, wherein said thermoelectric modules (10) are electrically connected to each other in series and / or in parallel. 16. Refrigerating system according to claim 14 or 15, wherein said thermoelectric modules (10) form one or more? cold springs and also form one or more? hot springs from which heat is removed by the coolant. 17. Refrigerating system according to one of claims 1,7,8, comprising temperature sensor means {25, 26; 31,32) to control the temperature of the circuit for removing heat from said hot plate (11) and to control the temperature of the room to be cooled. 18. Refrigerating system according to claim 5, comprising temperature sensor means (25,26) for controlling the temperature of the circuit for removing heat from said hot plate (11) and for controlling the temperature of the environment to be cooled, and also including a? unit? command and control electronics (27) connected to said thermoelectric module (10), to said pump (18), to said fan (21,) and to said temperature sensor means (25,26), to command the activation of the thermoelectric module (10) and the activation of the pump (18) and the fan (21) as a function of the temperature data supplied by the temperature sensor means (25,26). 19. A refrigerating system according to claim 1, wherein said refrigerant liquid? moved by a pump (18) along a closed circuit to remove heat from said hot plate (11) and to transfer heat to the outside through a heat exchanger (19) on which a fan (21) acts, and in which a liquid heat exchange? moved by a further pump (18?) along a closed circuit so as to come into contact with said cold plate (12) cooling down and so as to absorb heat from the environment to be cooled through a? further heat exchanger (19?) on which a further fan (21?) acts, the refrigerating system comprising temperature sensor means for controlling the temperature of the circuit for removing the heat from said hot plate (11) and for controlling the temperature of the room to be cooled, and including a? unit? command and control electronics (30) connected to said thermoelectric module (10), to said pumps (18,18?), to said fans (21,21?) and to said temperature sensor means (31,32), for command the activation of the thermoelectric module (10) and the activation of the pumps (18.18?) and the fans (21.21?) according to the temperature data supplied by the temperature sensor means (31.32). 20. Refrigerating system according to any one of the preceding claims, applied to a refrigerator. 21. Refrigerating system according to any one of claims 1 to 19, applied to an air conditioner.