FR3083594A1 - THERMAL INSTALLATION - Google Patents

Abstract

The invention relates to a thermal installation (100) comprising a tank (102) containing a first coil (s1) and a second coil (s2), a reversible exchanger (104) supplied by a heat transfer fluid which circulates in the first coil (s1 ), an aerothermal exchanger (106) which comprises a set of rods (20) and a third pipe (c3) which are arranged to ensure a transfer of heat from one to the other, a unit of solar collectors with heat pipe ( 108) which comprises a plurality of heat pipes (22) and a fourth pipe (c4) which are arranged to ensure a transfer of heat from one to the other, a geothermal exchanger (110) which comprises a thermal mass (26) and a third coil (s3) embedded in the thermal mass (26), a reversible heat pump (112), and a network of pipes, valves and pumps which channels a fourth heat transfer fluid between the second coil (s2), the aerothermal exchanger (106), the heat pipe solar collector unit (108), the geothermal heat exchanger (110), and the heat pump (112).

Description

THERMAL INSTALLATION

TECHNICAL AREA

The present invention relates to a thermal installation for heating or cooling a building.

STATE OF THE PRIOR ART

In order to reduce dependence on fossil fuels, it is known to use renewable energies to heat or cool a building. Although the current systems are entirely satisfactory, it is necessary to find more efficient installations.

STATEMENT OF THE INVENTION

An object of the present invention is to provide a more modular and efficient thermal installation.

To this end, a thermal installation is proposed comprising:

- a balloon containing a first heat transfer fluid and a first coil and a second coil which are immersed in the first heat transfer fluid,

- a reversible exchanger capable of supplying hot or cold in a building and supplied with a second heat transfer fluid which circulates in the first coil,

- an aerothermal exchanger which comprises a set of rods and a third pipe which are arranged so as to ensure a transfer of heat from one to the other,

- a heat pipe solar collector unit which comprises a plurality of heat pipes and a fourth pipe which are arranged so as to ensure a transfer of heat from one to the other,

- a geothermal exchanger which includes a thermal mass and a third coil embedded in the thermal mass,

a reversible heat pump comprising in series on a closed loop pipe, a pump, a first heat exchanger, a pressure reducer and a second heat exchanger in which a third heat transfer fluid circulates,

- a network of pipes, valves and pumps which channels a fourth heat transfer fluid between the second coil, the aerothermal exchanger, the heat pipe solar collector unit, the geothermal exchanger, and the heat pump.

According to a particular embodiment, the reversible exchanger is hydraulically connected in series between the inlet and the outlet of the first coil, and the network of pipes, valves and pumps comprises:

- a second pump placed at the entrance to the fourth pipe,

a first pipe which crosses the first heat exchanger and which is hydraulically connected between the outlet of the second coil and a third three-way solenoid valve,

- a second hydraulic line connected between the third solenoid valve and the inlet of the second coil and equipped with a first pump,

a fifth pipe which extends between a fourth three-way solenoid valve and a fifth four-way solenoid valve, where between the fourth solenoid valve and the fifth solenoid valve, the fifth pipe crosses the second heat exchanger, and where between the second heat exchanger and the fifth solenoid valve, the fifth pipe is equipped with a third pump,

- a sixth hydraulic line connected between the fourth solenoid valve and a sixth three-way solenoid valve,

- a seventh hydraulic line connected between the sixth solenoid valve and the inlet of the third line,

- an eighth pipe connected between the fifth solenoid valve and a seventh solenoid valve,

- a ninth line hydraulically connected between the sixth solenoid valve and the seventh solenoid valve,

- a tenth hydraulically connected pipe between the seventh solenoid valve and the outlet of the third coil,

- an eleventh line hydraulically connected between the fifth solenoid valve and an eighth three-way solenoid valve,

- a twelfth hydraulically connected pipe between the eighth solenoid valve and the inlet of the third coil,

- a thirteenth hydraulically connected pipe between the seventh solenoid valve and a ninth three-way solenoid valve, one of which is hydraulically connected to the second pump,

- a fourteenth line hydraulically connected between the eighth solenoid valve and a tenth three-way solenoid valve which is hydraulically connected to the outlet of the third line,

- a fifteenth hydraulically connected pipe between the tenth solenoid valve and an eleventh three-way solenoid valve,

- a sixteenth line hydraulically connected between the eleventh solenoid valve and the ninth solenoid valve,

a seventeenth hydraulically connected pipe between the seventh pipe and a twelfth two-way solenoid valve which is hydraulically connected to the outlet of the fourth pipe,

an eighteenth line hydraulically connected between the sixth line and a thirteenth two-way solenoid valve which is hydraulically connected to the outlet of the fourth line,

- a nineteenth line hydraulically connected between the eighth line and the eleventh solenoid valve,

a twentieth line hydraulically connected between the sixth line and a fourteenth two-way solenoid valve which is hydraulically connected to the fifth line at the outlet of the third pump,

- a twenty-first hydraulic line connected to the third solenoid valve and the fourth solenoid valve,

- a twenty-second hydraulic line connected between a fifteenth two-way solenoid valve and a sixteenth two-way solenoid valve, where the fifteenth solenoid valve is hydraulically connected to the fifth line at the inlet of the third pump, and where the sixteenth solenoid valve is hydraulically connected to the first pipe at the outlet of the second coil,

- a twenty-third hydraulic line connected between the fifth solenoid valve and the inlet of the third line.

According to a particular embodiment, the thermal installation comprises:

- a first three-way solenoid valve located upstream of the reversible exchanger,

- a second three-way solenoid valve located downstream of the reversible exchanger,

- a seventeenth three-way solenoid valve hydraulically connected between the first solenoid valve and the outlet of the first coil,

- an eighteenth three-way solenoid valve hydraulically connected between the second solenoid valve and the inlet of the first coil,

- a chilled water tank, a first outlet of which is hydraulically connected to the first solenoid valve, a first inlet of which is hydraulically connected to the second solenoid valve, of which a second inlet, a second outlet, the first inlet and the first outlet open into the chilled water tank,

- an absorption machine comprising a concentrator, a condenser, an evaporator and an absorber, where the evaporator comprises a fourth coil whose inlet is hydraulically connected to the second outlet of the chilled water tank and whose outlet is hydraulically connected at the second inlet of the chilled water tank, where the concentrator comprises a fifth coil whose inlet is hydraulically connected to the seventeenth solenoid valve and whose outlet is hydraulically connected to the eighteenth solenoid valve, where the absorber comprises a sixth coil having an inlet and an outlet, where the capacitor comprises a seventh coil with an inlet hydraulically connected to the outlet of the sixth coil and an outlet, and the network of pipes, valves and pumps comprises:

- a second pump arranged at the inlet of the fourth pipe,

a first pipe which crosses the first heat exchanger and which is hydraulically connected between the outlet of the second coil and a third three-way solenoid valve,

- a second hydraulic line connected between the third solenoid valve and the inlet of the second coil, and equipped with a first pump,

a fifth pipe which extends between a fourth three-way solenoid valve and a fifth four-way solenoid valve, where between the fourth solenoid valve and the fifth solenoid valve, the fifth pipe crosses the second heat exchanger, and where between the second heat exchanger and the fifth solenoid valve, the fifth pipe is equipped with a third pump,

- a sixth hydraulic line connected between the fourth solenoid valve and a sixth three-way solenoid valve,

a seventh hydraulic line connected between the sixth solenoid valve and the inlet of the third line,

- an eighth line hydraulically connected between the fifth solenoid valve and a seventh solenoid valve,

- a ninth line hydraulically connected between the sixth solenoid valve and the seventh solenoid valve,

- a tenth hydraulically connected pipe between the seventh solenoid valve and the outlet of the third coil,

- an eleventh line hydraulically connected between the fifth solenoid valve and an eighth three-way solenoid valve,

- a twelfth hydraulic line connected between the eighth solenoid valve and the inlet of the third coil,

- a thirteenth hydraulically connected pipe between the seventh solenoid valve and a ninth three-way solenoid valve, one of which is hydraulically connected to the second pump,

- a fifteenth line hydraulically connected between the outlet of the third line and an eleventh three-way solenoid valve,

- a sixteenth line hydraulically connected between the eleventh solenoid valve and the ninth solenoid valve,

a seventeenth hydraulically connected pipe between the seventh pipe and a twelfth two-way solenoid valve which is hydraulically connected to the outlet of the fourth pipe,

an eighteenth line hydraulically connected between the sixth line and a thirteenth two-way solenoid valve which is hydraulically connected to the outlet of the fourth line,

- a nineteenth line hydraulically connected between the eighth line and the eleventh solenoid valve,

a twentieth line hydraulically connected between the sixth line and a fourteenth two-way solenoid valve which is hydraulically connected to the fifth line at the outlet of the third pump,

a twenty-first hydraulic line connected between the third solenoid valve and the fourth solenoid valve,

- a twenty-second hydraulic line connected between a fifteenth two-way solenoid valve and a sixteenth two-way solenoid valve, where the fifteenth solenoid valve is hydraulically connected to the fifth line at the inlet of the third pump, and where the sixteenth solenoid valve is hydraulically connected to the first pipe at the outlet of the second coil,

- a twenty-third hydraulic line connected between the fifth solenoid valve and the inlet of the third line,

- a twenty-fourth hydraulically connected pipe between the eighth solenoid valve and the outlet of the seventh coil,

- a nineteenth three-way solenoid valve hydraulically connected to the tenth pipe between the seventh solenoid valve and the outlet of the third coil,

- a twenty-fifth hydraulically connected pipe between the nineteenth solenoid valve and the inlet of the sixth coil.

According to a particular embodiment, the thermal installation comprises:

- a first three-way solenoid valve located upstream of the reversible exchanger,

- a second three-way solenoid valve located downstream of the reversible exchanger,

- a seventeenth three-way solenoid valve hydraulically connected between the first solenoid valve and the outlet of the first coil,

- an eighteenth three-way solenoid valve hydraulically connected between the second solenoid valve and the inlet of the first coil,

- an eighth coil embedded in the thermal mass,

- a chilled water tank, a first outlet of which is hydraulically connected to the first solenoid valve, a first inlet of which is hydraulically connected to the second solenoid valve, of which a second inlet, a second outlet, the first inlet and the first outlet open into the chilled water tank,

- an absorption machine comprising a concentrator, a condenser, an evaporator and an absorber, where the evaporator comprises a fourth coil whose inlet is hydraulically connected to the second outlet of the chilled water tank and whose outlet is hydraulically connected at the second inlet of the chilled water tank, where the concentrator comprises a fifth coil whose inlet is hydraulically connected to the seventeenth solenoid valve and whose outlet is hydraulically connected to the eighteenth solenoid valve, where the absorber comprises a sixth coil having an inlet and an outlet, where the capacitor comprises a seventh coil with an inlet hydraulically connected to the outlet of the sixth coil and an outlet, and the network of pipes, valves and pumps comprises:

- a second pump arranged at the inlet of the fourth pipe,

a first pipe which crosses the first heat exchanger and which is hydraulically connected between the outlet of the second coil and a third three-way solenoid valve,

- a second hydraulic line connected between the third solenoid valve and the inlet of the second coil, and equipped with a first pump,

a fifth pipe which extends between a fourth three-way solenoid valve and a fifth four-way solenoid valve, where between the fourth solenoid valve and the fifth solenoid valve, the fifth pipe crosses the second heat exchanger, and where between the second heat exchanger and the fifth solenoid valve, the fifth pipe is equipped with a third pump,

- a sixth hydraulic line connected between the fourth solenoid valve and a sixth three-way solenoid valve,

a seventh hydraulic line connected between the sixth solenoid valve and the inlet of the third line,

- an eighth pipe connected between the fifth solenoid valve and a seventh solenoid valve,

- a ninth line hydraulically connected between the sixth solenoid valve and the seventh solenoid valve,

- a tenth hydraulically connected pipe between the seventh solenoid valve and the outlet of the third coil,

- a twelfth hydraulic line connected between the fifth solenoid valve and the inlet of the third coil,

- a thirteenth hydraulically connected pipe between the seventh solenoid valve and a ninth three-way solenoid valve, one of which is hydraulically connected to the second pump,

- a fifteenth line hydraulically connected between the outlet of the third line and an eleventh three-way solenoid valve,

- a sixteenth line hydraulically connected between the eleventh solenoid valve and the ninth solenoid valve,

a seventeenth hydraulically connected pipe between the seventh pipe and a twelfth two-way solenoid valve which is hydraulically connected to the outlet of the fourth pipe,

an eighteenth line hydraulically connected between the sixth line and a thirteenth two-way solenoid valve which is hydraulically connected to the outlet of the fourth line,

- a nineteenth line hydraulically connected between the eighth line and the eleventh solenoid valve,

a twentieth line hydraulically connected between the sixth line and a fourteenth two-way solenoid valve which is hydraulically connected to the fifth line at the outlet of the third pump,

a twenty-first hydraulic line connected between the third solenoid valve and the fourth solenoid valve,

- a twenty-second hydraulic line connected between a fifteenth two-way solenoid valve and a sixteenth two-way solenoid valve, where the fifteenth solenoid valve is hydraulically connected to the fifth line at the inlet of the third pump, and where the sixteenth solenoid valve is hydraulically connected to the first pipe at the outlet of the second coil,

- a twenty-third hydraulic line connected between the fifth solenoid valve and the inlet of the third line,

- a twenty-sixth hydraulically connected pipe between the inlet of the eighth coil and the outlet of the seventh coil,

- a twenty-seventh hydraulically connected pipe between the outlet of the eighth coil and the inlet of the sixth coil.

BRIEF DESCRIPTION OF THE DRAWINGS

The characteristics of the invention mentioned above, as well as others, will appear more clearly on reading the following description of an exemplary embodiment, said description being made in relation to the accompanying drawings, among which:

Fig. 1 shows a functional schematic representation of a thermal installation according to a first embodiment of the invention, FIG. 2 shows a functional schematic representation of a thermal installation according to a second embodiment of the invention, FIG. 3 shows a functional schematic representation of a thermal installation according to a third embodiment of the invention, and FIG. 4 shows a functional schematic representation of an absorption machine implemented in the second mode and the third embodiment of the invention.

DETAILED DESCRIPTION OF EMBODIMENTS

Fig. 1 shows a thermal installation 100 according to a first embodiment of the invention. Fig. 2 shows a thermal installation 200 according to a second embodiment of the invention and FIG. 3 shows a thermal installation 300 according to a third embodiment of the invention.

The thermal installation 100, 200, 300 includes:

a balloon 102 containing a first heat transfer fluid and a first coil if and a second coil s2 which are immersed in the first heat transfer fluid,

a reversible exchanger 104 capable of supplying hot or cold in a building and supplied with a second heat transfer fluid which circulates in the first coil if,

- an aerothermal exchanger 106,

- a unit of solar collectors with heat pipe 108,

- a geothermal exchanger 110,

- a heat pump 112, and

- a network of pipes, valves and pumps which channels a fourth heat transfer fluid between the second coil s2, the aerothermal exchanger 106, the unit of solar collectors with heat pipe 108, the geothermal exchanger 110, and the heat pump 112.

The three energy sources 106, 108 and 110 are hydraulically connected in series to supply the heat pump 112.

The heat pump 112 is reversible and conventionally comprises in series on a closed loop pipe, a pump 6, a first heat exchanger 8, a pressure reducer 10 and a second heat exchanger 12 in which a third heat transfer fluid circulates. Reversibility is ensured by the fact that the pump 6 can generate a circulation of the third heat transfer fluid in one direction or the other.

Each coil if, s2 has an input esl-es2 and an output osl-os2.

The first embodiment of the invention will now be described in detail.

A second heat transfer fluid circulates in the first coil if. The second heat transfer fluid enters the first coil if through the esl inlet and exits the first coil if through the osl outlet.

The reversible exchanger 104 is hydraulically connected in series between the inlet esl and the outlet osl of the first coil if. Thus, when the second heat transfer fluid exits through the osl outlet, it passes through the reversible exchanger 104 and returns to the esl inlet. In order to authorize or prohibit the circulation of the second heat transfer fluid, a first two-way solenoid valve v1 is disposed upstream of the reversible exchanger 104 and a second two-way solenoid valve v2 is arranged downstream of the reversible exchanger 104 The arrows fl and f2 show the direction of circulation of the second heat transfer fluid.

A first pipe cl is filled with a fourth heat transfer fluid and is hydraulically connected between the outlet os2 of the second coil s2 and a third three-way solenoid valve v3. The first pipe cl crosses the first heat exchanger 8 in order to be able to carry out a heat exchange with the pipe of the heat pump 112.

A second pipe c2 is hydraulically connected between the third solenoid valve v3 and the inlet es2, and is equipped with a first pump 16 which generates a circulation of the fourth heat transfer fluid successively through the inlet es2, the second coil s2, the outlet os2, the first pipe cl which crosses the first heat exchanger 8, the third solenoid valve v3, the second pipe c2, for a return to the first pump 16 and to the inlet es2.

The aerothermal exchanger 106 comprises a set of rods 20, in particular metallic, and a third pipe c3 in which the fourth heat transfer fluid circulates. The third pipe c3 and the rods 20 are arranged in such a way that the heat contained in the hot source, namely, as the case may be, the rods 20 or the fourth heat transfer fluid, transfers to the cold source, namely the fourth heat transfer fluid or the rods 20. According to a particular embodiment, the third pipe c3 and the rods 20 are in contact to ensure heat transfer.

The third pipe c3 has an inlet e3 and an outlet o3, and the fourth heat transfer fluid enters the aerothermal exchanger 106 through the inlet e3, circulates along the third pipe c3 to ensure thermal transfer with the rods 20 and spring by exit o3.

The heat pipe solar collector unit 108 comprises a plurality of heat pipes 22 and a fourth pipe c4 in which the fourth heat transfer fluid circulates. The heat pipes 22 and the fourth pipe c4 are arranged in such a way that the heat contained in the hot source, namely the heat pipes 22, is transferred to the cold source, namely the fourth heat transfer fluid.

The arrangement between the heat pipes 22 and the fourth pipe c4 is known to a person skilled in the art.

The fourth pipe c4 has an inlet e4 and an outlet o4 and the fourth heat-transfer fluid enters the solar heat collector unit 108 through the inlet e4, circulates along the fourth pipe c4 to ensure thermal transfer with the heat pipes 22 and comes out through outlet o4.

The geothermal exchanger 110 comprises a thermal mass 26 which is used to store heat and a third coil s3 which is embedded in the thermal mass 26. The third coil s3 has an input es3 and an output os3. The thermal mass 26 is preferably placed in the ground.

The fourth heat transfer fluid enters the geothermal exchanger 110 through the inlet es3, circulates along the third coil 28 to ensure thermal transfer with the thermal mass 26 and exits through the outlet os3.

The thermal installation 100 also includes a plurality of pipes which make it possible to connect the balloon 102, the aerothermal exchanger 106, the heat pipe solar collector unit 108, the geothermal exchanger 110 and the heat pump 112 between them.

The thermal installation 100 also comprises a plurality of pumps which make it possible to set in motion the fourth heat transfer fluid in the plurality of pipes.

The thermal installation 100 also includes a plurality of solenoid valves which make it possible to direct the fourth heat transfer fluid to one or the other of the pipes.

The thermal installation 100 comprises a second pump 28 and a third pump 29.

The second pump 28 is arranged at the inlet e4 of the fourth pipe c4 so as to drive the fourth heat transfer fluid in the direction described above.

The thermal installation 100 comprises a fifth line c5 which extends between a fourth three-way valve v4 and a fifth four-way valve v5. Between the fourth solenoid valve v4 and the fifth solenoid valve v5, the fifth pipe c5 passes through the second heat exchanger 12 in order to be able to carry out heat exchange with the pipe of the heat pump 112.

Between the second heat exchanger 12 and the fifth solenoid valve v5, the fifth pipe c5 is equipped with the third pump 29 which drives the fourth heat transfer fluid from the fourth solenoid valve v4 to the fifth solenoid valve v5.

Line sixth line c6 is hydraulically connected between the fourth solenoid valve v4 and a sixth three-way solenoid valve v6.

Line seventh line c7 is hydraulically connected between the sixth solenoid valve v6 and the inlet e3 of the third line c3.

The thermal installation 100 comprises a seventh four-way solenoid valve v7, an eighth line c8 hydraulically connected between the fifth solenoid valve v5 and the seventh solenoid valve v7, a ninth line c9 hydraulically connected between the sixth solenoid valve v6 and the seventh solenoid valve v7.

The thermal installation 100 comprises a tenth line C1 hydraulically connected between the seventh solenoid valve v7 and the outlet os3 of the third coil s3.

The thermal installation 100 comprises an eleventh eyelash line hydraulically connected between the fifth solenoid valve v5 and an eighth three-way solenoid valve v8, a twelfth line cl2 hydraulically connected between the eighth solenoid valve v8 and the inlet es3 of the third coil s3.

The thermal installation 100 comprises a thirteenth line cl3 hydraulically connected between the seventh solenoid valve v7 and a ninth three-way solenoid valve v9. The second pump 28 is hydraulically connected between the ninth solenoid valve v9 and the inlet e4 of the fourth pipe c4.

The thermal installation 100 comprises a fourteenth line cl4 hydraulically connected between the eighth solenoid valve v8 and a tenth three-way solenoid valve v10.

The output o3 of the third pipe c3 is hydraulically connected to the tenth solenoid valve vlO.

The thermal installation 100 comprises a fifteenth line cl5 hydraulically connected between the tenth solenoid valve v10 and an eleventh vile three-way solenoid valve, and a sixteenth line cl6 hydraulically connected between the eleventh solenoid valve vl 1 and the ninth solenoid valve v9.

The thermal installation 100 comprises a seventeenth pipe cl7 hydraulically connected between the seventh pipe c7 and a twelfth two-way valve vl2 which is hydraulically connected to the outlet o4 of the fourth pipe c4.

The thermal installation 100 comprises an eighteenth line cl8 hydraulically connected between the sixth line c6 and a thirteenth two-way valve vl3 which is hydraulically connected to the outlet o4 of the fourth line c4.

The thermal installation 100 comprises a nineteenth line cl9 hydraulically connected between the eighth line cl8 and the eleventh vile solenoid valve.

The thermal installation 100 comprises a twentieth line c20 hydraulically connected between the sixth line c6 and a fourteenth two-way valve vl4 which is hydraulically connected to the fifth line c5 at the outlet of the third pump 29.

The thermal installation 100 comprises a twenty-first line c21 hydraulically connected to the third solenoid valve v3 and the fourth solenoid valve v4.

The thermal installation 100 comprises a twenty-second line c22 hydraulically connected between a fifteenth two-way vl5 solenoid valve and a sixteenth two-way vl6 solenoid valve.

The fifteenth solenoid valve v5 is hydraulically connected to the fifth pipe c5 at the inlet of the third pump 29.

The sixteenth solenoid valve vl6 is hydraulically connected to the first pipe cl at the outlet os2 of the second coil s2.

A twenty-third line c23 is hydraulically connected between the fifth solenoid valve v5 and the inlet e3 of the third line c3.

The various solenoid valves and pumps are controlled in opening and closing by a control unit according to the desired use for the thermal installation 100 as described below.

The thermal installation 100 can operate in heating only with the heat pipe solar collector unit 108.

The solenoid valves vl2 and vl4 are closed.

There is no movement of fluid through the solenoid valves vlO, vil, v8, v6.

The solenoid valves vl3, vl5 and vl6 are open.

The fourth solenoid valve v4 is open between the sixth line c6 and the twenty-first line c21.

The third solenoid valve v3 is open between the twenty-first line c21 and the second line c2.

The fifth solenoid valve v5 is open between the fifth line c5 and the eighth line c8.

The seventh solenoid valve v7 is open between the eighth line c8 and the thirteenth line cl3.

The ninth solenoid valve v9 is open between the thirteenth line cl3 and the inlet e4 of the fourth line c4.

The fourth heat transfer fluid is then driven by the first pump 16, the second pump 28 and the third pump 29 and circulates from the outlet o4, and successively through the elements referenced: vl3, cl8, c6, v4, c21, v3, c2 , 16, es2, s2, os2, cl, vl6, c22, vl5, c5, 29, v5, c8, v7, cl3, v9, 28, e4, c4, o4.

The first heat transfer fluid is then heated by the second coil s2, which makes it possible to heat the second heat transfer fluid through the first coil if and to ensure the heating through the reversible exchanger 104.

The thermal installation 100 can operate in heating with the heat pipe solar collector unit 108, the aerothermal exchanger 106 and the heat pump 112.

The heat pump 112 is activated and the third heat transfer fluid circulates in the direction of the pump 6 through the first heat exchanger 8, then through the pressure reducer 10, then through the second heat exchanger 12 and a return to the pump 6 .

The solenoid valves vl2, v7, vl4, vl5, vl6 are closed.

There is no movement of fluid through the solenoid valves v6, v8.

The solenoid valve vl3 is open.

The tenth solenoid valve v10 is open between the outlet o3 of the third pipe c3 and the fifteenth pipe cl5.

The eleventh vil solenoid valve is open between the fifteenth line cl5 and the sixteenth line cl6.

The ninth solenoid valve v9 is open between the sixteenth line cl6 and the inlet e4 of the fourth line c4.

The fourth solenoid valve v4 is open between the sixth line c6 and the fifth line c5.

The fifth solenoid valve v5 is open between the fifth line c5 and the inlet e3 of the third line c3 through the twenty-third line c23.

The third solenoid valve v3 is open between the first line cl and the second line c2.

For a first part, the fourth fluid is then entrained by the second pump 28 and the third pump 29 and circulates from the third pump 29, and successively through the elements referenced: v5, c23, e3, c3, o3, vlO, cl5 , vil, cl6, v9, 28, e4, c4, o4, vl3, cl8, c6, v4, c5, 29.

The first part of the fourth fluid is thus heated successively by the aerothermal exchanger 106, then by the heat pipe solar collector unit 108, in order to supply heat to the heat pump 112.

For a second part, the fourth fluid circulates in a loop between the first pipe cl and the second pipe c2 under the action of the first pump 16 by passing through the first heat exchanger 8 in order to bring heat to the second coil s2, this which makes it possible to heat the second heat transfer fluid through the first coil if and ensure the heating through the reversible exchanger 104.

The thermal installation 100 can operate in heating with the heat pipe solar collector unit 108, the aerothermal exchanger 106, the geothermal exchanger 110 and the heat pump 112.

The heat pump 112 is activated and the third heat transfer fluid circulates from the pump 6 through the first heat exchanger 8, then through the pressure reducer 10, then through the second heat exchanger 12 and a return to the pump 6.

The solenoid valves vl2, vl4, vl5, vl6 are closed.

The solenoid valve vl3 is open.

The tenth solenoid valve v10 is open between the outlet o3 of the third pipe c3 and the fifteenth pipe cl5.

The eleventh vil solenoid valve is open between the fifteenth line cl5 and the sixteenth line cl6.

The ninth solenoid valve v9 is open between the sixteenth line cl6 and the inlet e4 of the fourth line c4.

The fourth solenoid valve v4 is open between the sixth line c6 and the fifth line c5.

The fifth solenoid valve v5 is open between the fifth line c5 and the eleventh eyelash line.

The eighth solenoid valve v8 is open between the eleventh line eyelash and the twelfth line cl2.

The seventh solenoid valve v7 is open between the tenth line clO and the ninth line c9.

The sixth solenoid valve v6 is open between the ninth line c9 and the seventh line c7.

The third solenoid valve v3 is open between the first line cl and the second line c2.

For a first part, the fourth fluid is then entrained by the second pump 28 and the third pump 29 and circulates from the third pump 29, and successively through the elements referenced: v5, eyelash, v8, cl2, es3, s3, os3 , clO, v7, c9, v6, c7, e3, c3, o3, vlO, cl5, vil, cl6, v9, 28, e4, c4, o4, vl3, cl8, c6, v4, c5, 29.

The first part of the fourth fluid is thus heated successively by the geothermal exchanger 110, by the aerothermal exchanger 106, then by the heat pipe solar collector unit 108, in order to supply heat to the heat pump 112.

For a second part, the fourth fluid circulates in a loop between the first pipe cl and the second pipe c2 under the action of the first pump 16 by passing through the first heat exchanger 8 in order to bring heat to the second coil s2, this which makes it possible to heat the second heat transfer fluid through the first coil if and ensure the heating through the reversible exchanger 104.

The thermal installation 100 can operate in air conditioning with the heat pipe solar collector unit 108, the aerothermal exchanger 106, the geothermal exchanger 110 and the heat pump 112.

The heat pump 112 is activated and the third heat transfer fluid circulates from the pump 6 through the second heat exchanger 12, then through the pressure reducer 10, then through the first heat exchanger 8, and a return to the pump 6.

The solenoid valves vl3, vl4, vl5, vl6 are closed.

There is no movement of fluid through the vile solenoid valve.

The solenoid valve vl2 is open.

The fifth solenoid valve v5 is open between the fifth line c5 and the eighth line c8.

The seventh solenoid valve v7 is open between the eighth line c8 and the thirteenth line cl3.

The ninth solenoid valve v9 is open between the thirteenth line cl3 and the inlet e4 of the fourth line c4.

The tenth solenoid valve v10 is open between the outlet o3 of the third pipe c3 and the fourteenth pipe cl4.

The eighth solenoid valve v8 is open between the fourteenth line cl4 and the twelfth line cl2.

The seventh solenoid valve v7 is also open between the tenth line clO and the ninth line c9.

The sixth solenoid valve v6 is open between the ninth line c9 and the sixth line c6.

The fourth solenoid valve v4 is open between the sixth line c6 and the fifth line c5.

For a first part, the fourth fluid is then entrained by the second pump 28 and the third pump 29 and circulates from the third pump 29, and successively through the elements referenced: v5, c8, v7, cl3, v9, 28, e4 , c4, o4, vl2, cl7, c7, e3, c3, o3, vlO, cl4, v8, cl2, es3, s3, os3, clO, v7, c9, v6, c6, v4, c5, 29.

The first part of the fourth fluid is thus firstly heated by the heat pipe solar collector unit 108, then cooled successively by the aerothermal exchanger 106, then by the geothermal exchanger 110, in order to extract heat from the heat pump 112. The passage through the unit of solar collectors with heat pipe 108 makes it possible to cool the heat pipes 22 and thus dissipate the heat that they store. In addition, the fact of extracting heat from the thermal mass 26 makes it possible to heat it and thus store heat for possible later use.

For a second part, the fourth fluid circulates in a loop between the first pipe cl and the second pipe c2 under the action of the first pump 16 by passing through the first heat exchanger 8 in order to cool the second coil s2 and therefore the second heat transfer fluid and thus extract the heat contained in the second heat transfer fluid through the first coil if and provide air conditioning through the reversible exchanger 104.

The thermal installation 100 can operate in air conditioning with the geothermal exchanger 110 and the heat pump 112 while the aerothermal exchanger 106 dissipates the heat stored by the heat pipes 22 of the heat collector solar unit 108.

The heat pump 112 is activated and the third heat transfer fluid circulates from the pump 6 through the second heat exchanger 12, then through the pressure reducer 10, then through the first heat exchanger 8, and a return to the pump 6.

The solenoid valves vl3, vl4, vl5, vl6 are closed.

The solenoid valve vl2 is open.

The fifth solenoid valve v5 is open between the fifth line c5 and the eleventh eyelash line.

The eighth solenoid valve v8 is open between the eleventh line eyelash and the twelfth line cl2.

The seventh solenoid valve v7 is open between the tenth line clO and the ninth line c9.

The sixth solenoid valve v6 is open between the ninth line c9 and the sixth line c6.

The fourth solenoid valve v4 is open between the sixth line c6 and the fifth line c5.

The tenth solenoid valve v10 is open between the outlet o3 of the third pipe c3 and the fifteenth pipe cl5.

The eleventh vil solenoid valve is open between the fifteenth line cl5 and the sixteenth line cl6.

The ninth solenoid valve v9 is open between the sixteenth line cl6 and the inlet e4 of the fourth line c4.

For a first part, the fourth fluid is then entrained by the third pump 29 and circulates from the third pump 29, and successively through the elements referenced: v5, cil, v8, cl2, es3, s3, os3, clO, v7, c9, v6, c6, v4, c5, 29.

The first part of the fourth fluid is thus cooled by the geothermal exchanger 110, in order to extract heat from the heat pump 112. In addition, the fact of extracting heat at the level of the thermal mass 26 makes it possible to heat it and thus store heat for possible later use.

For a second part of the fourth fluid, the fourth fluid circulates in a loop between the first pipe cl and the second pipe c2 under the action of the first pump 16 by passing through the first heat exchanger 8 in order to cool the second coil s2 and therefore the second heat transfer fluid and thus extract the heat contained in the second heat transfer fluid through the first coil if and provide air conditioning through the reversible exchanger 104.

For a third part, the fourth fluid is then entrained by the second pump 28 and circulates from the second pump 28, and successively through the elements referenced: e4, c4, o4, vl2, cl7, c7, e3, c3, o3, vlO, cl5, vil, cl6, v9, 28.

This third part makes it possible to cool the heat pipes 22 and thus dissipate the heat that they store.

The thermal installation 100 can operate to dissipate the heat from the heat pipes 22 using the geothermal heat exchanger 110, the air heat exchanger 106 and the heat pipe solar collector unit 108.

The heat pump 112 is deactivated.

The solenoid valves vl3, vl5, vl6, vl, v2 are closed.

There is no movement of fluid through the solenoid valves v4, v3.

The first pump 16 and the third pump 29 are deactivated.

The solenoid valves vl2, vl4 are open.

The tenth solenoid valve v10 is open between the outlet o3 of the third pipe c3 and the fifteenth pipe cl5.

The eleventh vile solenoid valve is open between the fifteenth line cl5 and the nineteenth line cl9.

The fifth solenoid valve v5 is open between the fifth line c5 and the eleventh eyelash line.

The eighth solenoid valve v8 is open between the eleventh line eyelash and the twelfth line cl2.

The seventh solenoid valve v7 is open between the tenth line clO and the thirteenth line cl3.

The ninth solenoid valve v9 is open between the thirteenth line cl3 and the fourth line c4.

The fourth fluid is then entrained by the second pump 28 and circulates from the second pump 28, and successively through the elements referenced: e4, c4, o4, vl2, cl7, c7, e3, c3, o3, vlO, cl5, vil , cl9, cl8, c6, c20, vl4, c5, v5, cil, v8, cl2, es3, s3, os3, clO, v7, cl3, v9, 28.

The fourth fluid is thus cooled by the aerothermal exchanger 106 then by the geothermal exchanger 110, in order to extract the heat from the heat pipes 22. In addition, the fact of extracting heat from the thermal mass 26 makes it possible to heat it and thus store heat for possible later use.

In the embodiments of Figs. 2 and 3, the thermal installation 200, 300 also includes an absorption machine 400 which is detailed in FIG. 4. The same elements as those of the first embodiment bear the same references.

In these two embodiments, the first solenoid valve v1 and the second two-way solenoid valve v2 are replaced by a first three-way solenoid valve v’I and a second three-way solenoid valve v’2.

The osl outlet of the first coil si is fitted with a seventeenth three-way solenoid valve vl7 hydraulically connected between the first solenoid valve v ’1 and the osl outlet of the first coil si.

The esl inlet of the first coil si is fitted with an eighteenth three-way solenoid valve vl8 hydraulically connected between the second solenoid valve v’2 and the esl inlet of the first coil si.

The thermal installation 200, 300 comprises a chilled water tank 402 whose first outlet orl is hydraulically connected to the first solenoid valve v’I and whose first inlet erl is hydraulically connected to the second solenoid valve v’2. The chilled water tank 402 also has a second inlet er2 and a second outlet or2. The first inlet erl, the first outlet orl, the second inlet er2 and the second outlet or2 open into the chilled water tank 402.

The refrigerated water tank 402 includes a refrigeration system, not shown.

The absorption machine 400 includes a concentrator 404, a condenser 406, an evaporator 408 and an absorber 410.

The evaporator 408 has a fourth coil s4 whose inlet is hydraulically connected to the second outlet or2 of the chilled water tank 402 and whose outlet is hydraulically connected to the second inlet er2 of the chilled water tank 402.

The principle consists in spraying water into fine droplets in the evaporator 408 under vacuum using a sprayer 412. Due to the low pressure, the water evaporates. For this, it needs a certain amount of heat which is extracted from the water to be cooled, circulating in the fourth coil s4 through the evaporator 408. The water which is found in the lower part of the evaporator 408 is reintroduced into the sprayer 412 using an appropriate pump and pipe.

The water vapor created in the evaporator 408 is brought to the absorber 410 by an absorption pipe 414. The absorber 410 contains an absorbent solution which is continuously pumped into the bottom of the container to be sprayed there by a pump. , a suitable pipeline and sprayer. The absorbent solution absorbs water vapor from the evaporator 408 and thus maintains the low pressure necessary for the vaporization of the refrigerant.

To limit the rise in temperature of the absorbent solution in the absorber 410, the latter comprises a sixth coil s6 comprising an inlet es6 and an outlet os6 and in which a fluid at low temperature circulates, here the fourth heat transfer fluid.

The absorbent solution is regenerated in the concentrator 404 where it is brought by a regeneration line 416 equipped with a pump. The concentrator 404 comprises a fifth coil s5, an inlet of which is hydraulically connected to the seventeenth solenoid valve v17 and the outlet of which is hydraulically connected to the eighteenth solenoid valve vl8. The absorbent solution is then heated by the fifth coil s5 and part of the water evaporates. The regenerated absorbent solution returns to the absorber 410 through an appropriate pipe.

The capacitor 406 comprises a seventh coil s 7 with an input es7 which is hydraulically connected to the output os6 of the sixth coil s6 and an output os7.

The water vapor extracted from the concentrator 404 is brought into the condenser 406 by an appropriate pipe, where it is cooled by a circulation of cold water in the seventh coil s7 and the water thus condensed returns to the evaporator 408 by a appropriate pipeline.

In heating mode, the absorption machine 400 is switched off, and the solenoid valves v'I, v'2, vl7 and vl8 are open so that the second heat transfer fluid leaves via the osl outlet, passes through the reversible exchanger 104 by crossing the seventeenth solenoid valve vl7 and the first solenoid valve v'I, then returns to the input esl by crossing the second solenoid valve v'2 and the eighteenth solenoid valve vl8.

The connections of the solenoid valves v’I, v’2, vl7 and vl8 to the absorption machine 400 and the chilled water tank 402 are closed.

In air conditioning mode, the absorption machine 400 is started as described above. In addition, the v'I, v'2, vl7 and vl8 are open so that, on the one hand, the second heat transfer fluid leaves through the osl outlet, joins the absorption machine 400 and crosses the fifth coil s5 through the seventeenth solenoid valve vl7, then joins the inlet esl through the eighteenth solenoid valve vl8, and, in such a way that, on the other hand, a heat transfer fluid circulates in the fourth coil s4 by looping in the chilled water tank 402.

The second heat transfer fluid flows through the reversible exchanger 104 through the second solenoid valve v’2, the chilled water tank 402 and the first solenoid valve v’I, for a return to the reversible exchanger 104.

The connections of the seventeenth solenoid valve vl7 to the first solenoid valve v’I, and of the eighteenth solenoid valve vl8 to the second solenoid valve v’2 are closed.

Compared to the first embodiment, the thermal installation 200 according to the second embodiment does not include a fourteenth line cl4 nor a tenth solenoid valve vlO. The fifteenth line cl5 is then hydraulically connected between the output o3 of the third line c3 and the eleventh vile three-way solenoid valve,

Compared to the first embodiment, the thermal installation 200 comprises a twenty-fourth pipe c24 hydraulically connected between the eighth solenoid valve v8 and the output os7 of the seventh coil s7.

The thermal installation 200 also comprises a nineteenth three-way vl9 solenoid valve hydraulically connected to the tenth line clO between the seventh solenoid valve v7 and the os3 outlet of the third coil s3.

The thermal installation 200 also includes a twenty-fifth line c25 hydraulically connected between the nineteenth solenoid valve vl9 and the inlet es6 of the sixth coil s6.

The thermal installation 200 can operate in heating only with the heat pipe solar collector unit 108. The absorption machine 400 is switched off and the second heat transfer fluid circulates as described above in the heating mode.

The solenoid valves vl2, vl4etvl9 are closed.

There is no movement of fluid through the vil, v6, v8, vl9 solenoid valves.

The solenoid valves vl3, vl5 and vl6 are open.

The fourth solenoid valve v4 is open between the sixth line c6 and the twenty-first line c21.

The third solenoid valve v3 is open between the twenty-first line c21 and the second line c2.

The fifth solenoid valve v5 is open between the fifth line c5 and the eighth line c8.

The seventh solenoid valve v7 is open between the eighth line c8 and the thirteenth line cl3.

The ninth solenoid valve v9 is open between the thirteenth line cl3 and the inlet e4 of the fourth line c4.

The fourth heat transfer fluid is then driven by the first pump 16, the second pump 28 and the third pump 29 and circulates from the outlet o4, and successively through the elements referenced: vl3, cl8, c6, v4, c21, v3, c2 , 16, es2, s2, os2, cl, vl6, c22, vl5, c5, 29, v5, c8, v7, cl3, v9, 28, e4, c4, o4.

The first heat transfer fluid is then heated by the second coil s2, which makes it possible to heat the second heat transfer fluid through the first coil if and to ensure the heating through the reversible exchanger 104.

The thermal installation 200 can operate in heating with the heat pipe solar collector unit 108, the aerothermal exchanger 106 and the heat pump 112. The absorption machine 400 is switched off and the second heat transfer fluid circulates as described below. above in heating mode.

The heat pump 112 is activated and the third heat transfer fluid circulates in the direction of the pump 6 through the first heat exchanger 8, then through the pressure reducer 10, then through the second heat exchanger 12 and a return to the pump 6 .

The solenoid valves vl2, v7, vl4, vl5, vl6 are closed.

There is no movement of fluid through the solenoid valves v6, v8, vl9. The solenoid valve vl3 is open.

The eleventh vil solenoid valve is open between the fifteenth line cl5 and the sixteenth line cl6.

The ninth solenoid valve v9 is open between the sixteenth line cl6 and the inlet e4 of the fourth line c4.

The fourth solenoid valve v4 is open between the sixth line c6 and the fifth line c5.

The fifth solenoid valve v5 is open between the fifth line c5 and the inlet e3 of the third line c3 through the twenty-third line c23.

The third solenoid valve v3 is open between the first line cl and the second line c2.

For a first part, the fourth fluid is then entrained by the second pump 28 and the third pump 29 and circulates from the third pump 29, and successively through the elements referenced: v5, c23, e3, c3, o3, cl5, vil , cl6, v9, 28, e4, c4, o4, vl3, cl8, c6, v4, c5, 29.

The first part of the fourth fluid is thus heated successively by the aerothermal exchanger 106, then by the heat pipe solar collector unit 108, in order to supply heat to the heat pump 112.

For a second part, the fourth fluid circulates in a loop between the first pipe cl and the second pipe c2 under the action of the first pump 16 by passing through the first heat exchanger 8 in order to bring heat to the second coil s2, this which makes it possible to heat the second heat transfer fluid through the first coil if and ensure the heating through the reversible exchanger 104.

The thermal installation 200 can operate in heating with the heat pipe solar collector unit 108, the aerothermal exchanger 106, the geothermal exchanger 110 and the heat pump 112. The absorption machine 400 is switched off and the second heat transfer fluid circulates as described above in the heating mode.

The heat pump 112 is activated and the third heat transfer fluid circulates from the pump 6 through the first heat exchanger 8, then through the pressure reducer 10, then through the second heat exchanger 12 and a return to the pump 6.

The solenoid valves vl2, vl4, vl5, vl6 are closed.

The solenoid valve vl3 is open.

The eleventh vil solenoid valve is open between the fifteenth line cl5 and the sixteenth line cl6.

The ninth solenoid valve v9 is open between the sixteenth line cl6 and the inlet e4 of the fourth line c4.

The fourth solenoid valve v4 is open between the sixth line c6 and the fifth line c5.

The fifth solenoid valve v5 is open between the fifth line c5 and the eleventh eyelash line.

The eighth solenoid valve v8 is open between the eleventh line eyelash and the twelfth line cl2.

The seventh solenoid valve v7 is open between the tenth line clO and the ninth line c9.

The sixth solenoid valve v6 is open between the ninth line c9 and the seventh line c7.

The third solenoid valve v3 is open between the first line cl and the second line c2.

The nineteenth solenoid valve v9 is open between the tenth line clO and the seventh solenoid valve v7.

For a first part, the fourth fluid is then entrained by the second pump 28 and the third pump 29 and circulates from the third pump 29, and successively through the elements referenced: v5, cil, v8, cl2, es3, s3, os3 , clO, vl9, v7, c9, v6, c7, e3, c3, o3, cl5, vil, cl6, v9, 28, e4, c4, o4, vl3, cl8, c6, v4, c5, 29.

The first part of the fourth fluid is thus heated successively by the geothermal exchanger 110, by the aerothermal exchanger 106, then by the heat pipe solar collector unit 108, in order to supply heat to the heat pump 112.

For a second part, the fourth fluid circulates in a loop between the first pipe cl and the second pipe c2 under the action of the first pump 16 by passing through the first heat exchanger 8 in order to bring heat to the second coil s2, this which makes it possible to heat the second heat transfer fluid through the first coil if and ensure the heating through the reversible exchanger 104.

The thermal installation 200 can operate in air conditioning with the heat pipe solar collector unit 108, the aerothermal exchanger 106, the geothermal exchanger 110 and the heat pump 112. The absorption machine 400 is put into operation and the second heat transfer fluid circulates as described above in the air conditioning mode.

The heat pump 112 is activated and the third heat transfer fluid circulates from the pump 6 through the second heat exchanger 12, then through the pressure reducer 10, then through the first heat exchanger 8, and a return to the pump 6.

The solenoid valves vl2, v7, vl4, vl5, vl6 are closed.

There is no movement of fluid through the solenoid valve v6.

The solenoid valve vl3 is open.

The fifth solenoid valve v5 is open between the fifth line c5 and the twenty-third line c23.

The ninth solenoid valve v9 is open between the sixteenth line cl6 and the inlet e4 of the fourth line c4.

The eleventh vil solenoid valve is open between the fifteenth line cl5 and the sixteenth line cl6.

The eighth solenoid valve v8 is open between the twenty-fourth line c24 and the twelfth line cl2.

The fourth solenoid valve v4 is open between the sixth line c6 and the fifth line c5.

The third solenoid valve v3 is open between the first line cl and the second line c2.

The nineteenth solenoid valve vl9 is open between the twenty-fifth line c25 and the output os3 of the third coil s3 through the tenth line clO.

For a first part, the fourth fluid is then entrained by the second pump 28 and the third pump 29 and circulates from the third pump 29, and successively through the elements referenced: v5, c23, e3, c3, o3, cl5, vil , cl6, v9, 28, e4, c4, o4, vl3, cl8, c6, v4, c5, 29.

For a second part, the fourth fluid circulates in a loop between the first pipe cl and the second pipe c2 under the action of the first pump 16 by passing through the first heat exchanger 8 in order to cool the second coil s2 and therefore the second heat transfer fluid and thus extract the heat contained in the second heat transfer fluid through the first coil if and provide air conditioning through the reversible exchanger 104.

For a third part, the fourth fluid circulates from the absorption machine 400, successively through the elements referenced: c24, v8, cl2, es3, s3, os3, clO, vl9, c25.

The thermal installation 200 can operate in air conditioning with the heat pipe solar collector unit 108 and the geothermal heat exchanger 110. The absorption machine 400 is put into operation and the second heat transfer fluid circulates as described above in the air conditioning mode .

The heat pump 112 is deactivated.

The solenoid valves vl2, vl4 are closed.

There is no movement of fluid through the vil, v6 solenoid valves.

The solenoid valves vl3, vl5, vl6 are open.

The fifth solenoid valve v5 is open between the fifth line c5 and the eighth line c8.

The seventh solenoid valve v7 is open between the eighth line c8 and the thirteenth line cl3.

The ninth solenoid valve v9 is open between the thirteenth line cl3 and the inlet e4 of the fourth line c4.

The eighth solenoid valve v8 is open between the twenty-fourth line c24 and the twelfth line cl2.

The fourth solenoid valve v4 is open between the sixth line c6 and the twenty-first line c21.

The third solenoid valve v3 is open between the twenty-first line c21 and the second line c2.

The nineteenth solenoid valve vl9 is open between the twenty-fifth line c25 and the output os3 of the third coil s3 through the tenth line clO.

For a first part, the fourth fluid is then entrained by the second pump 28 and the third pump 29 and circulates from the third pump 29, and successively through the elements referenced: v5, c8, v7, cl3, v9, 28, e4 , c4, o4, vl3, cl8, c6, v4, c21, v3, c2, 16, es2, s2, os2, cl, vl6, c22, vl5, c5, 29.

For a second part, the fourth fluid circulates from the absorption machine 400, successively through the referenced elements: c24, v8, cl2, es3, s3, os3, clO, vl9, c25.

The thermal installation 200 can operate to dissipate the heat from the heat pipes 22 by using the geothermal heat exchanger 110, the aerothermal heat exchanger 106 and the heat pipe solar collector unit 108. The absorption machine 400 is off as well as the reversible exchanger 104.

The solenoid valves vl3, vl5, vl6 are closed.

There is no movement of fluid through the solenoid valves v4, v6, v3, v’I, v’2, vl7, vl8.

The solenoid valves vl2 and vl4 are open.

The fifth solenoid valve v5 is open between the fifth line c5 and the eleventh eyelash line.

The seventh solenoid valve v7 is open between the tenth line clO and the thirteenth line cl3.

The ninth solenoid valve v9 is open between the thirteenth line cl3 and the inlet e4 of the fourth line c4.

The eleventh vile solenoid valve is open between the fifteenth line cl5 and the nineteenth line cl9.

The eighth solenoid valve v8 is open between the eleventh line eyelash and the twelfth line cl2.

The nineteenth solenoid valve v9 is open between the tenth line clO and the seventh solenoid valve v7.

The fourth fluid is then entrained by the second pump 28 and circulates from the second pump 28, and successively through the elements referenced: e4, c4, o4, vl2, cl7, c7, e3, c3, o3, cl5, vil, cl9 , cl8, c6, vl4, c5, v5, cil, v8, cl2, es3, s3, os3, clO, vl9, v7, cl3, v9, 28.

Compared to the first embodiment, the thermal installation 300 according to the third embodiment does not include a fourteenth line cl4, nor an eighth solenoid valve v8 and a tenth solenoid valve v10. The eleventh line cl 1 and the twelfth line cl2 are then identical.

Compared to the first embodiment, the thermal installation 300 comprises an eighth coil s8 which is embedded in the thermal mass 26 so as to provide heat exchange with the third coil s3 and the thermal mass 26.

The eighth coil s8 has an input es8 and an output os8.

The thermal installation 300 comprises a twenty-sixth pipeline c26 hydraulically connected between the inlet es8 of the eighth coil s8 and the outlet os7 of the seventh coil s7.

The thermal installation 300 also includes a twenty-seventh line c27 hydraulically connected between the outlet os8 of the eighth coil s8 and the inlet es6 of the sixth coil s6.

The thermal installation 300 can operate in heating only with the heat pipe solar collector unit 108. The absorption machine 400 is switched off and the second heat transfer fluid circulates as described above in the heating mode.

The solenoid valves vl2, vl4 are closed.

There is no movement of fluid through the vil, v6 solenoid valves.

The solenoid valves vl3, vl5 and vl6 are open.

The fourth solenoid valve v4 is open between the sixth line c6 and the twenty-first line c21.

The third solenoid valve v3 is open between the twenty-first line c21 and the second line c2.

The fifth solenoid valve v5 is open between the fifth line c5 and the eighth line c8.

The seventh solenoid valve v7 is open between the eighth line c8 and the thirteenth line cl3.

The ninth solenoid valve v9 is open between the thirteenth line cl3 and the inlet e4 of the fourth line c4.

The fourth heat transfer fluid is then driven by the first pump 16, the second pump 28 and the third pump 29 and circulates from the outlet o4, and successively through the elements referenced: vl3, cl8, c6, v4, c21, v3, c2 , 16, es2, s2, os2, cl, vl6, c22, vl5, c5, 29, v5, c8, v7, cl3, v9, 28, e4, c4, o4.

The first heat transfer fluid is then heated by the second coil s2, which makes it possible to heat the second heat transfer fluid through the first coil if and to ensure the heating through the reversible exchanger 104.

The thermal installation 300 can operate in heating with the heat pipe solar collector unit 108, the aerothermal exchanger 106 and the heat pump 112. The absorption machine 400 is switched off and the second heat transfer fluid circulates as described below. above in heating mode.

The heat pump 112 is activated and the third heat transfer fluid circulates in the direction of the pump 6 through the first heat exchanger 8, then through the pressure reducer 10, then through the second heat exchanger 12 and a return to the pump 6 .

The solenoid valves vl2, v7, vl4, vl5, vl6 are closed.

There is no movement of fluid through the solenoid valve v6.

The solenoid valve vl3 is open.

The eleventh vil solenoid valve is open between the fifteenth line cl5 and the sixteenth line cl6.

The ninth solenoid valve v9 is open between the sixteenth line cl6 and the inlet e4 of the fourth line c4.

The fourth solenoid valve v4 is open between the sixth line c6 and the fifth line c5.

The fifth solenoid valve v5 is open between the fifth line c5 and the inlet e3 of the third line c3 through the twenty-third line c23.

The third solenoid valve v3 is open between the first line cl and the second line c2.

For a first part, the fourth fluid is then entrained by the second pump 28 and the third pump 29 and circulates from the third pump 29, and successively through the elements referenced: v5, c23, e3, c3, o3, cl5, vil , cl6, v9, 28, e4, c4, o4, vl3, cl8, c6, v4, c5, 29.

For a second part, the fourth fluid circulates in a loop between the first pipe cl and the second pipe c2 under the action of the first pump 16 by passing through the first heat exchanger 8 in order to bring heat to the second coil s2, this which makes it possible to heat the second heat transfer fluid through the first coil if and ensure the heating through the reversible exchanger 104.

The thermal installation 300 can operate in heating with the heat pipe solar collector unit 108, the aerothermal exchanger 106, the geothermal exchanger 110 and the heat pump 112. The absorption machine 400 is switched off and the second heat transfer fluid circulates as described above in the heating mode.

The heat pump 112 is activated and the third heat transfer fluid circulates from the pump 6 through the first heat exchanger 8, then through the pressure reducer 10, then through the second heat exchanger 12 and a return to the pump 6.

The solenoid valves vl2, vl4, vl5, vl6 are closed.

The solenoid valve vl3 is open.

The eleventh vil solenoid valve is open between the fifteenth line cl5 and the sixteenth line cl6.

The ninth solenoid valve v9 is open between the sixteenth line cl6 and the inlet e4 of the fourth line c4.

The fourth solenoid valve v4 is open between the sixth line c6 and the fifth line c5.

The fifth solenoid valve v5 is open between the fifth line c5 and the twelfth line cl2.

The seventh solenoid valve v7 is open between the tenth line clO and the ninth line c9.

The sixth solenoid valve v6 is open between the ninth line c9 and the seventh line c7.

The third solenoid valve v3 is open between the first line cl and the second line c2.

For a first part, the fourth fluid is then entrained by the second pump 28 and the third pump 29 and circulates from the third pump 29, and successively through the elements referenced: v5, cl2, es3, s3, os3, clO, v7 , c9, v6, c7, e3, c3, o3, cl5, vil, cl6, v9, 28, e4, c4, o4, vl3, cl8, c6, v4, c5, 29.

For a second part, the fourth fluid circulates in a loop between the first pipe cl and the second pipe c2 under the action of the first pump 16 by passing through the first heat exchanger 8 in order to bring heat to the second coil s2, this which makes it possible to heat the second heat transfer fluid through the first coil if and ensure the heating through the reversible exchanger 104.

The thermal installation 300 can operate in air conditioning with the heat pipe solar collector unit 108, the aerothermal exchanger 106, the geothermal exchanger 110 and the heat pump 112. The absorption machine 400 is put into operation and the second heat transfer fluid circulates as described above in the air conditioning mode.

The heat pump 112 is activated and the third heat transfer fluid circulates from the pump 6 through the second heat exchanger 12, then through the pressure reducer 10, then through the first heat exchanger 8, and a return to the pump 6.

The solenoid valves vl2, v7, vl4, vl5, vl6 are closed.

There is no movement of fluid through the solenoid valve v6.

The solenoid valve vl3 is open.

The fifth solenoid valve v5 is open between the fifth line c5 and the twenty-third line c23.

The ninth solenoid valve v9 is open between the sixteenth line cl6 and the inlet e4 of the fourth line c4.

The eleventh vil solenoid valve is open between the fifteenth line cl5 and the sixteenth line cl6.

The fourth solenoid valve v4 is open between the sixth line c6 and the fifth line c5.

The third solenoid valve v3 is open between the first line cl and the second line c2.

For a first part, the fourth fluid is then entrained by the second pump 28 and the third pump 29 and circulates from the third pump 29, and successively through the elements referenced: v5, c23, e3, c3, o3, cl5, vil , cl6, v9, 28, e4, c4, o4, vl3, cl8, c6, v4, c5, 29.

For a second part, the fourth fluid circulates in a loop between the first pipe cl and the second pipe c2 under the action of the first pump 16 by passing through the first heat exchanger 8 in order to cool the second coil s2 and therefore the second heat transfer fluid and thus extract the heat contained in the second heat transfer fluid through the first coil if and provide air conditioning through the reversible exchanger 104.

For a third part, the fourth fluid circulates from the absorption machine 400, successively through the elements referenced: c26, es8, s8, os8, c27.

The thermal installation 300 can operate in air conditioning with the heat pipe solar collector unit 108 and the geothermal exchanger 110. The absorption machine 400 is put into operation and the second heat transfer fluid circulates as described above in the air conditioning mode .

The heat pump 112 is deactivated.

The solenoid valves vl2, vl4 are closed.

There is no movement of fluid through the solenoid valves vl 1, v6.

The solenoid valves vl3, vl5, vl6 are open.

The fifth solenoid valve v5 is open between the fifth line c5 and the eighth line c8.

The seventh solenoid valve v7 is open between the eighth line c8 and the thirteenth line cl3.

The ninth solenoid valve v9 is open between the thirteenth line cl3 and the inlet e4 of the fourth line c4.

The fourth solenoid valve v4 is open between the sixth line c6 and the twenty-first line c21.

The third solenoid valve v3 is open between the twenty-first line c21 and the second line c2.

For a first part, the fourth fluid is then entrained by the second pump 28 and the third pump 29 and circulates from the third pump 29, and successively through the elements referenced: v5, c8, v7, cl3, v9, 28, e4 , c4, o4, vl3, cl8, c6, v4, c21, v3, c2, 16, es2, s2, os2, cl, vl6, c22, vl5, c5, 29.

For a third part, the fourth fluid circulates from the absorption machine 400, successively through the elements referenced: c26, es8, s8, os8, c27.

The thermal installation 300 can operate in air conditioning with the heat pipe solar collector unit 108, the aerothermal exchanger 106, the geothermal exchanger 110 and the heat pump 112. The absorption machine 400 is put into operation and the second heat transfer fluid circulates as described above in the air conditioning mode.

The heat pump 112 is activated and the third heat transfer fluid circulates from the pump 6 through the second heat exchanger 12, then through the pressure reducer 10, then through the first heat exchanger 8, and a return to the pump 6.

The solenoid valves vl2, vl4, vl5, vl6 are closed.

There is no movement of fluid through the solenoid valve v6.

The solenoid valve vl3 is open.

The fifth solenoid valve v5 is open between the fifth line c5 and the twelfth line cl2.

The seventh solenoid valve v7 is open between the tenth line clO and the ninth line c9.

The sixth solenoid valve v6 is open between the ninth line c9 and the seventh line c7.

The ninth solenoid valve v9 is open between the sixteenth line cl6 and the inlet e4 of the fourth line c4.

The eleventh vil solenoid valve is open between the fifteenth line cl5 and the sixteenth line cl6.

The fourth solenoid valve v4 is open between the sixth line c6 and the fifth line c5.

The third solenoid valve v3 is open between the first line cl and the second line c2.

For a first part, the fourth fluid is then entrained by the second pump 28 and the third pump 29 and circulates from the third pump 29, and successively through the elements referenced: v5, cl2, es3, s3, os3, clO, v7 , c9, v6, c7, e3, c3, o3, cl5, vil, cl6, v9, 28, e4, c4, o4, vl3, cl8, c6, v4, c5, 29.

For a second part, the fourth fluid circulates in a loop between the first pipe cl and the second pipe c2 under the action of the first pump 16 by passing through the first heat exchanger 8 in order to cool the second coil s2 and therefore the second heat transfer fluid and thus extract the heat contained in the second heat transfer fluid through the first coil if and provide air conditioning through the reversible exchanger 104.

For a third part, the fourth fluid circulates from the absorption machine 400, successively through the elements referenced: c26, es8, s8, os8, c27.

The thermal installation 300 can operate to dissipate the heat from the heat pipes 22 by using the geothermal heat exchanger 110, the aerothermal heat exchanger 106 and the heat pipe solar collector unit 108. The absorption machine 400 is off as well as the reversible exchanger 104.

The solenoid valves vl3, vl5, vl6 are closed.

There is no movement of fluid through the solenoid valves v4, v6, v3, v’I, v’2, vl7, vl8.

The solenoid valves vl2 and vl4 are open.

The fifth solenoid valve v5 is open between the fifth line c5 and the twelfth line cl2.

The seventh solenoid valve v7 is open between the tenth line clO and the thirteenth line cl3.

The ninth solenoid valve v9 is open between the thirteenth line cl3 and the inlet e4 of the fourth line c4.

The eleventh vile solenoid valve is open between the fifteenth line cl5 and the nineteenth line cl9.

The fourth fluid is then entrained by the second pump 28 and circulates from the second pump 28, and successively through the elements referenced: e4, c4, o4, vl2, cl7, c7, e3, c3, o3, cl5, vil, cl9 , cl8, c6, vl4, c5, v5, cl2, es3, s3, os3, clO, v! 9, v7, c! 3, v9, 28.

Claims (5)

1) Thermal installation (100) comprising: - a balloon (102) containing a first heat transfer fluid and a first coil (si) and a second coil (s2) which are immersed in the first heat transfer fluid, - a reversible exchanger (104) capable of supplying hot or cold in a building and supplied with a second heat transfer fluid which circulates in the first coil (if), - an aerothermal exchanger (106) which comprises a set of rods (20), and a third pipe (c3) which are arranged so as to ensure a transfer of heat from one to the other, - a heat pipe solar collector unit (108) which comprises a plurality of heat pipes (22) and a fourth pipe (c4) which are arranged so as to ensure a transfer of heat from one to the other, - a geothermal exchanger (110) which comprises a thermal mass (26) and a third coil (s3) embedded in the thermal mass (26), - a reversible heat pump (112) comprising in series on a closed loop pipe, a pump (6), a first heat exchanger (8), a pressure reducer (10) and a second heat exchanger (12) in which a third heat transfer fluid, - a network of pipes, valves and pumps which channels a fourth heat transfer fluid between the second coil (s2), the aerothermal exchanger (106), the unit of solar collectors with heat pipe (108), the geothermal exchanger ( 110), and the heat pump (112). 2) thermal installation (100) according to claim 1, characterized in that the reversible exchanger (104) is hydraulically connected in series between the inlet (esl) and the outlet (osl) of the first coil (si), and in what the network of pipes, valves and pumps includes: - a second pump (28) disposed at the inlet (e4) of the fourth pipe (c4), - a first pipe (cl) which crosses the first heat exchanger (8) and which is hydraulically connected between the outlet (os2) of the second coil (s2) and a third three-way solenoid valve (v3), - a second pipeline (c2) hydraulically connected between the third solenoid valve (v3) and the inlet (es2) of the second coil (s2) and equipped with a first pump (16), - a fifth pipe (c5) which extends between a fourth three-way solenoid valve (v4) and a fifth four-way solenoid valve (v5), where between the fourth solenoid valve (v4) and the fifth solenoid valve (v5), the fifth pipe (c5) passes through the second heat exchanger (12), and where between the second heat exchanger (12) and the fifth solenoid valve (v5), the fifth pipe (c5) is equipped with a third pump (29), a sixth pipeline (c6) hydraulically connected between the fourth solenoid valve (v4) and a sixth three-way solenoid valve (v6), - a seventh line (c7) hydraulically connected between the sixth solenoid valve (v6) and the inlet (e3) of the third line (c3), - an eighth pipe (c8) connected between the fifth solenoid valve (v5) and a seventh solenoid valve (v7), - a ninth line (c9) hydraulically connected between the sixth solenoid valve (v6) and the seventh solenoid valve (v7), - a tenth line (clO) hydraulically connected between the seventh solenoid valve (v7) and the outlet (os3) of the third coil (s3), - an eleventh line (eyelash) hydraulically connected between the fifth solenoid valve (v5) and an eighth three-way solenoid valve (v8), - a twelfth line (cl2) hydraulically connected between the eighth solenoid valve (v8) and the inlet (es3) of the third coil (s3), a thirteenth pipe (cl3) hydraulically connected between the seventh solenoid valve (v7) and a ninth three-way solenoid valve (v9), one of which is hydraulically connected to the second pump (28), - a fourteenth line (cl4) hydraulically connected between the eighth solenoid valve (v8) and a tenth three-way solenoid valve (vlO) which is hydraulically connected to the outlet (o3) of the third line (c3), - a fifteenth line (cl5) hydraulically connected between the tenth solenoid valve (vlO) and an eleventh three-way solenoid valve (vl 1), - a sixteenth line (cl6) hydraulically connected between the eleventh solenoid valve (vl 1) and the ninth solenoid valve (v9), a seventeenth line (cl7) hydraulically connected between the seventh line (c7) and a twelfth two-way solenoid valve (vl2) which is hydraulically connected to the outlet (o4) of the fourth line (c4), - an eighteenth line (cl8) hydraulically connected between the sixth line (c6) and a thirteenth two-way solenoid valve (vl3) which is hydraulically connected to the outlet (o4) of the fourth line (c4), - a nineteenth line (cl9) hydraulically connected between the eighth line (cl8) and the eleventh solenoid valve (vl 1), a twentieth line (c20) hydraulically connected between the sixth line (c6) and a fourteenth two-way solenoid valve (vl4) which is hydraulically connected to the fifth line (c5) at the outlet of the third pump (29), - a twenty-first line (c21) hydraulically connected to the third solenoid valve (v3) and the fourth solenoid valve (v4), - a twenty-second line (c22) hydraulically connected between a fifteenth two-way solenoid valve (vl5) and a sixteenth two-way solenoid valve (vl6), where the fifteenth solenoid valve (vl5) is hydraulically connected to the fifth line (c5) inlet of the third pump (29), and where the sixteenth solenoid valve (vl6) is hydraulically connected to the first pipe (cl) at the outlet (os2) of the second coil (s2), - a twenty-third line (c23) hydraulically connected between the fifth solenoid valve (v5) and the inlet (e3) of the third line (c3). 3) Thermal installation (200) according to claim 1, characterized in that it comprises: - a first three-way solenoid valve (ν ’1) disposed upstream of the reversible exchanger (104), - a second three-way solenoid valve (v’2) disposed downstream of the reversible exchanger (104), - a seventeenth three-way solenoid valve (vl7) hydraulically connected between the first solenoid valve (ν ’1) and the outlet (osl) of the first coil (si), - an eighteenth three-way solenoid valve (vl8) hydraulically connected between the second solenoid valve (v’2) and the inlet (esl) of the first coil (si), - a chilled water tank (402) of which a first outlet (orl) is hydraulically connected to the first solenoid valve (ν '1), of which a first inlet (erl) is hydraulically connected to the second solenoid valve (v'2), a second inlet (er2), a second outlet (or2), the first inlet (erl) and the first outlet (orl) open into the chilled water tank (402), - an absorption machine (400) comprising a concentrator (404), a condenser (406), an evaporator (408) and an absorber (410), where the evaporator (408) comprises a fourth coil (s4) whose inlet is hydraulically connected to the second outlet (or2) of the chilled water tank (402) and whose outlet is hydraulically connected to the second inlet (er2) of the chilled water tank (402), where the concentrator (404) comprises a fifth coil (s5), an inlet of which is hydraulically connected to the seventeenth solenoid valve (vl7) and the outlet of which is hydraulically connected to the eighteenth solenoid valve (vl8), where the absorber (410) comprises a sixth coil (s6) having an input (es6) and an output (os6), where the capacitor (406) comprises a seventh coil (s7) with an input (es7) hydraulically connected to the output (os6) of the sixth coil (s6) and an output (os7), and in that the network d The pipes, valves and pumps include: - a second pump (28) disposed at the inlet (e4) of the fourth pipe (c4), - a first pipe (cl) which crosses the first heat exchanger (8) and which is hydraulically connected between the outlet (os2) of the second coil (s2) and a third three-way solenoid valve (v3), a second pipeline (c2) hydraulically connected between the third solenoid valve (v3) and the inlet (es2) of the second coil (s2), and equipped with a first pump (16), - a fifth pipe (c5) which extends between a fourth three-way solenoid valve (v4) and a fifth four-way solenoid valve (v5), where between the fourth solenoid valve (v4) and the fifth solenoid valve (v5), the fifth pipe (c5) passes through the second heat exchanger (12), and where between the second heat exchanger (12) and the fifth solenoid valve (v5), the fifth pipe (c5) is equipped with a third pump (29), a sixth pipe (c6) hydraulically connected between the fourth solenoid valve (v4) and a sixth three-way solenoid valve (v6), - a seventh line (c7) hydraulically connected between the sixth solenoid valve (v6) and the inlet (e3) of the third line (c3), - an eighth pipe (c8) hydrolically connected between the fifth solenoid valve (v5) and a seventh solenoid valve (v7), - a ninth line (c9) hydraulically connected between the sixth solenoid valve (v6) and the seventh solenoid valve (v7), - a tenth line (clO) hydraulically connected between the seventh solenoid valve (v7) and the outlet (os3) of the third coil (s3), - an eleventh line (eyelash) hydraulically connected between the fifth solenoid valve (v5) and an eighth three-way solenoid valve (v8), - a twelfth line (cl2) hydraulically connected between the eighth solenoid valve (v8) and the inlet (es3) of the third coil (s3), a thirteenth pipe (cl3) hydraulically connected between the seventh solenoid valve (v7) and a ninth three-way solenoid valve (v9), one of which is hydraulically connected to the second pump (28), - a fifteenth line (cl5) hydraulically connected between the outlet (o3) of the third line (c3) and an eleventh three-way solenoid valve (vl 1), - a sixteenth line (cl6) hydraulically connected between the eleventh solenoid valve (vl 1) and the ninth solenoid valve (v9), a seventeenth line (cl7) hydraulically connected between the seventh line (c7) and a twelfth two-way solenoid valve (vl2) which is hydraulically connected to the outlet (o4) of the fourth line (c4), - an eighteenth line (cl8) hydraulically connected between the sixth line (c6) and a thirteenth two-way solenoid valve (vl3) which is hydraulically connected to the outlet (o4) of the fourth line (c4), - a nineteenth line (cl9) hydraulically connected between the eighth line (cl8) and the eleventh solenoid valve (vl 1), a twentieth line (c20) hydraulically connected between the sixth line (c6) and a fourteenth two-way solenoid valve (vl4) which is hydraulically connected to the fifth line (c5) at the outlet of the third pump (29), - a twenty-first line (c21) hydraulically connected between the third solenoid valve (v3) and the fourth solenoid valve (v4), - a twenty-second line (c22) hydraulically connected between a fifteenth two-way solenoid valve (vl5) and a sixteenth two-way solenoid valve (vl6), where the fifteenth solenoid valve (vl5) is hydraulically connected to the fifth line (c5) inlet of the third pump (29), and where the sixteenth solenoid valve (vl6) is hydraulically connected to the first pipe (cl) at the outlet (os2) of the second coil (s2), - a twenty-third pipe (c23) hydraulically connected between the fifth solenoid valve (v5) and the inlet (e3) of the third pipe (c3), - a twenty-fourth pipe (c24) hydraulically connected between the eighth solenoid valve (v8) and the outlet (os7) of the seventh coil (s7), - a nineteenth three-way solenoid valve (vl9) hydraulically connected to the tenth pipe (clO) between the seventh solenoid valve (v7) and the outlet (os3) of the third coil (s3), - a twenty-fifth pipe (c25) hydraulically connected between the nineteenth solenoid valve (vl9) and the inlet (es6) of the sixth coil (s6). 4) Thermal installation (300) according to claim 1, characterized in that it comprises: - a first three-way solenoid valve (ν ’1) disposed upstream of the reversible exchanger (104), - a second three-way solenoid valve (v’2) disposed downstream of the reversible exchanger (104), - a seventeenth three-way solenoid valve (vl7) hydraulically connected between the first solenoid valve (ν ’1) and the outlet (osl) of the first coil (si), - an eighteenth three-way solenoid valve (vl8) hydraulically connected between the second solenoid valve (v’2) and the inlet (esl) of the first coil (si), - an eighth coil (s8) embedded in the thermal mass (26), - a chilled water tank (402) of which a first outlet (orl) is hydraulically connected to the first solenoid valve (ν '1), of which a first inlet (erl) is hydraulically connected to the second solenoid valve (v'2), a second inlet (er2), a second outlet (or2), the first inlet (erl) and the first outlet (orl) open into the chilled water tank (402), - an absorption machine (400) comprising a concentrator (404), a condenser (406), an evaporator (408) and an absorber (410), where the evaporator (408) comprises a fourth coil (s4) whose inlet is hydraulically connected to the second outlet (or2) of the chilled water tank (402) and whose outlet is hydraulically connected to the second inlet (er2) of the chilled water tank (402), where the concentrator (404) comprises a fifth coil (s5), an inlet of which is hydraulically connected to the seventeenth solenoid valve (vl7) and the outlet of which is hydraulically connected to the eighteenth solenoid valve (vl8), where the absorber (410) comprises a sixth coil (s6) having an input (es6) and an output (os6), where the capacitor (406) comprises a seventh coil (s7) with an input (es7) hydraulically connected to the output (os6) of the sixth coil (s6) and an output (os7), and in that the network d The pipes, valves and pumps include: - a second pump (28) disposed at the inlet (e4) of the fourth pipe (c4), - a first pipe (cl) which crosses the first heat exchanger (8) and which is hydraulically connected between the outlet (os2) of the second coil (s2) and a third three-way solenoid valve (v3), a second pipeline (c2) hydraulically connected between the third solenoid valve (v3) and the inlet (es2) of the second coil (s2), and equipped with a first pump (16), - a fifth pipe (c5) which extends between a fourth three-way solenoid valve (v4) and a fifth four-way solenoid valve (v5), where between the fourth solenoid valve (v4) and the fifth solenoid valve (v5), the fifth pipe (c5) passes through the second heat exchanger (12), and where between the second heat exchanger (12) and the fifth solenoid valve (v5), the fifth pipe (c5) is equipped with a third pump (29), a sixth pipe (c6) hydraulically connected between the fourth solenoid valve (v4) and a sixth three-way solenoid valve (v6), - a seventh line (c7) hydraulically connected between the sixth solenoid valve (v6) and the inlet (e3) of the third line (c3), - an eighth pipe (c8) connected between the fifth solenoid valve (v5) and a seventh solenoid valve (v7), - a ninth line (c9) hydraulically connected between the sixth solenoid valve (v6) and the seventh solenoid valve (v7), - a tenth line (clO) hydraulically connected between the seventh solenoid valve (v7) and the outlet (os3) of the third coil (s3), - a twelfth line (cl2) hydraulically connected between the fifth solenoid valve (v5) and the inlet (es3) of the third coil (s3), a thirteenth pipe (cl3) hydraulically connected between the seventh solenoid valve (v7) and a ninth three-way solenoid valve (v9), one of which is hydraulically connected to the second pump (28), - a fifteenth line (cl5) hydraulically connected between the outlet (o3) of the third line (c3) and an eleventh three-way solenoid valve (vl 1), - a sixteenth line (cl6) hydraulically connected between the eleventh solenoid valve (vl 1) and the ninth solenoid valve (v9), a seventeenth line (cl7) hydraulically connected between the seventh line (c7) and a twelfth two-way solenoid valve (vl2) which is hydraulically connected to the outlet (o4) of the fourth line (c4), - an eighteenth line (cl8) hydraulically connected between the sixth line (c6) and a thirteenth two-way solenoid valve (vl3) which is hydraulically connected to the outlet (o4) of the fourth line (c4), - a nineteenth line (cl9) hydraulically connected between the eighth line (cl8) and the eleventh solenoid valve (vl 1), a twentieth line (c20) hydraulically connected between the sixth line (c6) and a fourteenth two-way solenoid valve (vl4) which is hydraulically connected to the fifth line (c5) at the outlet of the third pump (29), - a twenty-first line (c21) hydraulically connected between the third solenoid valve (v3) and the fourth solenoid valve (v4), - a twenty-second line (c22) hydraulically connected between a fifteenth two-way solenoid valve (vl5) and a sixteenth two-way solenoid valve (vl6), where the fifteenth solenoid valve (vl5) is hydraulically connected to the fifth line (c5) inlet of the third pump (29), and where the sixteenth solenoid valve (vl6) is hydraulically connected to the first pipe (cl) at the outlet (os2) of the second coil (s2), - a twenty-third pipe (c23) hydraulically connected between the fifth solenoid valve (v5) and the inlet (e3) of the third pipe (c3), - a twenty-sixth pipe (c26) hydraulically connected between the inlet (es8) of the eighth coil (s8) and the outlet (os7) of the seventh coil (s7), 5 - a twenty-seventh pipe (c27) hydraulically connected between the outlet (os8) of the eighth coil (s8) and the inlet (es6) of the sixth coil (s6).