FR3016207A1 - HEAT PUMP PRODUCING COLD - Google Patents

Abstract

The invention relates to a heat pump system (1) adapted for cold production, comprising: - a main circuit (10) on which are successively arranged an evaporator (20), a compressor (11), a condenser (21) and an expander (12); a cold recovery circuit (30); a heat dissipation circuit (31); the main circuit (10), cold recovery circuit (30) and heat dissipation circuit (31) being water circuits in the liquid and / or vapor state; the evaporator (20) putting the water of the main circuit (10) in heat exchange by direct contact with the water of the cold recovery circuit (30), the condenser (21) putting the water of the main circuit (10) ) in heat exchange by direct contact with the water of the heat dissipation circuit (31); characterized in that the compressor (11) is an axial compressor directly coupled to the evaporator (20) and configured to increase the water vapor pressure of the main circuit (10) by at least 400%.

Description

GENERAL TECHNICAL FIELD The present invention relates to a heat pump producing cold. STATE OF THE ART A heat pump is a thermodynamic device designed to force a heat transfer from a cold source (from which the heat is extracted) to a hot source (where it is reinjected). Figure 1 shows the general architecture of a conventional heat pump. It comprises a circuit 10 of a phase change thermal fluid, on which are successively arranged: an evaporator 20, in heat exchange with a medium to be cooled (cold source) via a circuit 30, in which the thermal fluid passes in the gaseous state by absorbing the surrounding heat; a compressor 11 allowing a rise in pressure of the fluid; - A condenser 21, in heat exchange with a medium to be heated (hot source) via a circuit 31, wherein the fluid passes to the liquid state by releasing enthalpy in the form of heat; In a "cold production" oriented configuration, the cold source is the medium whose cooling is desired (the circuit 30 is then a cold recovery circuit) and the hot source is an external medium, in which especially the water of a river, the ambient air, the basement, etc. (The circuit 31 is thus a heat dissipation circuit). It will be noted that many heat pumps are alternatively used for heat production.

The advantage of a heat pump is its efficiency (or COP, coefficient of performance) greater than 1: part of the energy supplied by the pump is "free". The thermal fluids of circuit 10 for cold production are called refrigerants: they are capable of evaporating at a low temperature under atmospheric pressure. Refrigerants commonly used in refrigeration machines, however, pose a problem because they have an impact on the environment or on the safety of people. In particular: carbonaceous fluids, essentially HFCs (hydrofluorocarbons), have a greenhouse effect potential; - ammonia, is toxic and explosive; hydrocarbons are flammable; - CO2 requires very high pressures (100 bar). For these reasons, it has been proposed to use water as a refrigerant, which is a common, inexpensive fluid with no impact on the environment and without risk to the safety of people. However, using water today poses great technical difficulties (the processing of a huge amount of steam is required) which requires rethinking the architecture of the compressors. The patent application FR2800159 thus proposes a heat pump (water) in which the cold recovery and heat dissipation circuits also use water as coolant / heat transfer fluid. Insofar as water is then the fluid common to the three circuits, heat exchange by direct contact (that is to say without physical barrier, by mixing the fluids of the circuits) can be implemented in the evaporator and the condenser. This technique avoids heat losses at the exchangers and provides satisfaction. 30 The publication "Water as Refrigerant" by Madsboll, 23rd International Congress of Refrigeration, 21-26 August 2011, Prague, organized by International Institute of Refrigeration, Paper No. 765, proposes to use an axial compressor (usually used for compressions of gases other than water vapor and completely different applications, for example in jet engines) instead of known radial centrifugal compressors.

However, it is noted that these techniques are not enough today to commercially launch water heat pumps. The invention improves the situation.

PRESENTATION OF THE INVENTION The invention proposes to overcome these disadvantages by proposing in a first aspect a heat pump system adapted for cold production, comprising - a main circuit on which are successively arranged an evaporator, a compressor, a condenser and a regulator; - a cold recovery circuit; a heat dissipation circuit; the main circuit, cold recovery circuit and heat dissipation circuit being water circuits in the liquid and / or vapor state; the evaporator putting the water of the main circuit in heat exchange by direct contact with the water of the cold recovery circuit, the condenser putting the water of the main circuit in heat exchange by direct contact with the water of the dissipation circuit heat ; Characterized in that the compressor is an axial compressor directly coupled to the evaporator and configured to increase the water vapor pressure of the main circuit by at least 400%. The device according to the invention is advantageously completed by the following characteristics, taken alone or in any of their technically possible combination: the compressor is configured to increase the pressure of the water vapor of the main circuit by a factor understood between 500% and 700%; the compressor is configured to increase the pressure of the main circuit water vapor by approximately 600%; the system is configured so that the vapor pressure in the main circuit is less than 12 millibars at the inlet of the compressor, and greater than 50 millibars at the outlet of the compressor; the system is configured so that the vapor pressure in the main circuit is approximately 8 millibars at the inlet of the compressor, and approximately 56 millibars at the outlet of the compressor; - The system further comprises a desuperheater disposed on the main circuit between the compressor and the condenser, the desuperheater putting compressed water vapor of the main circuit in heat exchange with the fluid of a heat recovery circuit; The desuperheater is directly coupled to the compressor and the condenser; the system has the compressor, the desuperheater and the condenser stacked at a height less than the height of the evaporator, so that the compressor is coupled to the evaporator at an upper part of the evaporator, and the condenser is arranged vis-à-vis a lower part of the evaporator; the system further comprises a vacuum pump connected to the condenser for starting the system and regulating the operating pressure levels; The vacuum pump is connected to the condenser via at least one tapping at the top of the condenser; - The system further comprises a bypass circuit for the circulation of steam between the condenser and the evaporator when starting the system; The evaporator comprises at least one stirrer and / or at least one inclined plate; the heat dissipation circuit comprises at least one nozzle for spraying water in the condenser; the circuit further comprises a lubricating circuit of the compressor, the fluid of the lubrication circuit being water coming from a branch of the cold recovery circuit and / or from a branch of the heat dissipation circuit; the system further comprises a cooling circuit of the compressor, the fluid of the cooling circuit being water coming from a branch of the cold recovery circuit and / or a branch of the heat dissipation circuit; - Water is the only fluid used as thermal fluid or lubricating fluid. According to a second aspect, the invention relates to a method of producing cold using a heat pump system, the method being characterized in that it comprises steps of: - condensation of water vapor a main circuit in a heat exchange condenser by direct contact with water of a heat dissipation circuit; 20 - expansion of the liquid water in a pressure reducer; - vaporization of the liquid water in an evaporator in heat exchange by direct contact with water of a cold recovery circuit; compressing the water vapor by an axial compressor 25 directly coupled to the evaporator so as to increase the pressure of the water vapor of the main circuit by at least 400%; - returning the compressed steam to the condenser. According to advantageous characteristics: the expansion is carried out up to a pressure of less than 12 millibars, and the compression is carried out up to a pressure greater than 50 millibars; the step of returning the water vapor compressed in the condenser comprises the circulation of water vapor in a desuperheater in heat exchange with the fluid of a heat recovery circuit so as to cool the steam of main circuit water to a temperature below 40 ° C.

PRESENTATION OF THE FIGURES Other features, objects and advantages of the invention will emerge from the description which follows, which is purely illustrative and nonlimiting, and which should be read with reference to the accompanying drawings, in which: FIG. diagram of a known heat pump; FIG. 2 is a diagram of a preferred embodiment of the heat pump system according to the invention; FIG. 3 is a diagram of a compressor of an installation according to the invention; Figure 4 is a graph showing a Mollier diagram plotted on a phase diagram of water; FIG. 5 is a diagram of a detail of the evaporator-compressor connection; Figure 6 is a diagram of a detail of the compressor-desuperheater link; FIG. 7 is a diagram of a detail of the desuperheater-condenser connection. DETAILED DESCRIPTION Principle of the invention With reference to FIG. 2, the invention proposes a heat pump system 1 adapted for cold production. There is a main circuit 10 on which are successively arranged an evaporator 20, a compressor 11, a condenser 21 and a pressure reducer 12; a cold recovery circuit 30; and a heat dissipation circuit 31; the main circuit 10, cold recovery circuit 30 and heat dissipation circuit 31 being water circuits in the liquid state and / or steam. In particular, the main circuit 10 is a phase change circuit, so the water is in the liquid state on one part of the cycle and gaseous on the other part. As in the prior art FR2800159 cited, the evaporator 20 puts the water of the main circuit 10 in heat exchange by direct contact with the water of the cold recovery circuit 30, the condenser 21 putting water in the main circuit 10 in heat exchange by direct contact with a heat dissipation circuit 31. As explained by "direct contact", it is meant that the fluids of the three circuits 10, 30 and 31 are not separated by physical barriers, and therefore are in one and the same enclosure. In particular, as seen in the preferred example illustrated in FIG. 2, the water of the cold recovery circuit 30 enters the evaporator 20 at the bottom, where it mixes with the liquid water from the expander 12, and the water of the heat dissipation circuit 31 is sprayed into the condenser 21 at the top, where it mixes with the condensates of water vapor. The present system 1 is distinguished by the characteristics of the compressor 11. The latter is an axial compressor as evoked. An axial compressor comprises fixed wheels 114 and movable wheels 113 (not shown in Figure 2, but visible in Figure 3). The fixed wheels (called rectifiers) are fixed on a stator 112, the movable wheels 30 are fixed on a rotor 111. The fixed wheels 114 are equipped with so-called steerable blades (their foot can be subjected to a rotation whose angle can be adjusted according to the rotational speed of the rotor 111). An assembly of a fixed wheel 114 and a moving wheel 113 constitutes a stage. It has been found that the water used as a refrigerant requires, unlike conventional fluids (HFC, ammonia, etc.), a very high compression ratio, associated with a very large mass volume. Mass volume of saturated water vapor at 4 ° C (m3 / kg) Order of magnitude of the water compression ratio 157,117 7 HFC 134a 0,060 2,6 Ammonia NH3 0,252 2.7 In contrast to previous techniques, which have a rate of 2 to 4, the present compressor is configured to increase the pressure of the water vapor of the main circuit 10 by at least 400% (ie compression ratio of at least 5), advantageously configured to increase the water pressure of the main circuit 10 by a factor between 500% and 700% (ie compression ratio between 6 and 8), more preferably configured to increase the steam pressure of main circuit water of about 600% (ie 7 compression ratio). This corresponds to a vapor pressure in the main circuit 10 of less than 12 millibars (advantageously less than 9 millibars, and in particular about 8 millibar) at the inlet of the compressor 11, and greater than 50 millibars (in particular about 56 millibars) at the outlet It has never been possible until now to implement the required pressure levels. To thus configure the compressor 11, the Applicant had the idea of directly coupling the axial compressor to the evaporator. By "directly coupling" is meant that there is no circuit 10 piping between the two. In particular, the evaporator contains, in its upper part, a "manhole" finalized by a half-flange 100 (see Figure 5 which has this detail), and the envelope 110 of the compressor 11 is also equipped a half-flange 100 which is fixed on the half-flange 100 of the evaporator 20 so as to form the coupling. The "suction" part of the compressor 11 (in other words the first stages in the direction of circulation of the steam) can even be slightly nested in the evaporator 20, or even be substantially disposed inside the evaporator 20. This coupling makes it possible to limit the pressure losses even by conveying a particularly large volume of gas (as is necessary for the steam) and to reduce as much as possible the pressure within the evaporator 20. it is then sufficient to choose a number of stages such that it makes it possible to reach the required compression ratio. The speed of the wheels can be of the order of 9000 rpm for a wheel diameter of the order of 1.37 m. Evaporator The evaporator 20 is the component of the heat pump in which, under the effect of the low pressure which prevails, the water evaporates into water vapor by taking the heat from the ambient environment, in particular the return water from the cold recovery circuit 30. The evaporator 20 is advantageously equipped, in its lower part, with at least one stirrer 200 (or mixer), itself connected to a rotation shaft, itself actuated by a motor located outside the evaporator. Inclined plates 201, in particular metal plates, are advantageously welded to the lower part of the evaporator 20 at such an angle that they make it possible, thanks to the combined action of the stirrer 200, to homogenize a "grout. ice that can appear at temperatures near 0 ° C that prevail there. The agitator 200 also makes it possible to homogenize the temperature of the water and / or the slurry contained in the evaporator 20.

The evaporator 20 can be thermally insulated in its lower part. A tapping allows the suction of ice water / slurry (at a temperature around 5 ° C) in the cold recovery circuit 30 by a pump. A stitching still in its lower part, for example on the sidewall, allows the return of ice water / grout after recovery, and therefore at a higher temperature (about 12 ° C) or a lower ice concentration. The water vapor is located in the middle and upper part of the evaporator 20, present by direct heat exchange a temperature of about 5 ° C and a pressure of about 8 millibars. Desuperheater The high compression ratio obtained by the compressor 11 causes a significant increase in the temperature of the steam, it can exceed 100 ° C or even 200 ° C, and particularly preferably reach about 270 ° C. Preferably, a desuperheater 22 makes it possible to recover heat at a very high temperature (greater than 100 ° C.) at the discharge of the compressor via a heat recovery circuit 32. It will be understood that the desuperheater 22, it is present, differs from the condenser 21 in that it is not the place of any phase change. Unlike what happens in the evaporator 20 or condenser 21, it is not necessary that the heat exchange implemented by the desuperheater 22 is done by direct contact, nor that the heat transfer fluid of the circuit 32 is the same. water (although the choice of water is preferred). The desuperheater can thus be a heat exchanger that is conventionally found in commerce. It is supplied with superheated heat at over 100 ° C and at least 50 millibars by the compressor 11 in its upper part. Advantageously, the desuperheater uses a cooling of the steam to the limit of condensation (dew point). After heat exchange, the saturated steam is typically discharged in the lower part at about 34 ° C. towards the condenser 21.

The desuperheater 22 may be absent from the circuit 10. In this case, the desuperheating of the steam is done directly in the condenser 21. The advantage of the desuperheater 22 is to avoid dissipating (and therefore losing) all the thermal energy via the circuit 31 of heat dissipation, but to be able to recover a portion at sufficient temperature levels for example for various applications of heating or preheating (air, liquid, etc.) via the circuit 32, which is a heat recovery, and therefore to limit the share of heat dissipated via the circuit 31. The energy balance remains equivalent. Preferably, the compressor 11 is also coupled to the desuperheater 22: as seen in Figure 6, there is no piping between the two elements. The casing 110 of the compressor 11 contains, in the lower part of the discharge side, another half-flange 100. The casing 220 of the desuperheater 22, in its upper part and at its end, also comprises a half-flange 100 which comes attach to the half-flange of the compressor discharge.

The desuperheater can also be coupled to the condenser 21 by a flange system 100 identical to that of the compressor / desuperheater coupling. Condenser Condenser 21 is the component of the heat pump in which water vapor usually gives off its sensible heat as it cools, the water vapor gives up its latent heat as it condenses, and the water sometimes gives up its sensible heat. cooling (phenomenon called subcooling). The existence or not of the above phenomena depends on the dimensioning of the condenser 21 and the presence or absence of the desuperheater 22. In all cases, the heat transferred to the external medium (via the circuit 31 of heat dissipation) . The condenser 21 is supplied with saturated steam in the upper part by the desuperheater 22 (or directly by the compressor 11), the steam condenses through the distribution (see below) of liquid water at about 28 ° C back circuit 31 of heat dissipation. The liquid water at about 34 ° C is collected in the lower part of the condenser 21. The condenser 21 is equipped with a stitching so as to discharge the warm water to the circuit 31 of heat dissipation with the aid of a pump. An optional purge 210 empties too much condensate.

The condenser 21 can also be equipped with a nozzle in its upper part so as to connect it to a vacuum pump 13. The latter allows the start of the system 1 by initiating the pressure conditions required for its proper operation and can be necessary for the maintenance of the vacuum (ie the regulation of the pressure levels) during the operation of the system 1. The condenser 21 can also be equipped with one or more taps in its upper or middle part so as to connect it to the the evaporator 20 by a "bypass" circuit, in other words a circuit bypassing the main circuit 10 (and the expander 12). This bypass allows the start of the system 1 by initiating the circulation of steam in the entire system 1. It comprises at least one valve for closing it, triggered as soon as the operation of the system 1 is stabilized.

The cooling of the condenser 21 is advantageously ensured by a distribution of "rain" water in the upper part of the condenser 21: the return water of the heat dissipation circuit 31 (at about 28 ° C.) is distributed by a or several nozzles 311 located inside the condenser 21, which spray the water (see Figure 7). The water then falls back into the lower part of the condenser 21, capturing the latent heat of the surrounding water vapor. The evaporator 20 and the condenser 21 are connected by a branch of the main circuit 10 comprising a pipe provided with the expander 12 (for example a solenoid valve). The expansion (in particular up to about 8 millibars) is accompanied by a cooling of the water, as seen on the Mollier diagram (Figure 4) and allows the pressure balance.

With reference to this diagram, the system travels in the opposite direction of clockwise the drawn cycle. A 3 B: compression in the compressor 11; B 3 C: cooling in the desuperheater 22; C 3 D: condensation in the condenser 21; D 3 E: expansion in the expander 12; E 3 A: vaporization in the evaporator 20; Compactness of the system As explained, the evaporator 20, the compressor 11, the desuperheater 22 and the condenser 21 are preferably successively coupled in pairs. In other words, most of the circuit 10 (in this case the whole except the portion on which the regulator 12 is located) is formed by the envelopes of the components themselves. This allows a system architecture 1 comprising two blocks as shown in Figure 2: on one side the evaporator 20, and on the other side the compressor 11, the desuperheater 22 and condenser 21 stacked. The height of the evaporator 20 is at least equal to the height of the stack of the other three components, so as to allow the coupling of the evaporator 20 and the compressor 11 in the upper part, and to have the evaporator 20 disposed vis-à-vis the condenser 21, that is to say at the bottom. The branch of the circuit 10 allowing the communication between the condenser 21 and the evaporator 20 is then of minimum length. This architecture allows a minimal space requirement of the system 1 while limiting as much as possible the pressure losses due to the length of piping. It can be seen in FIG. 2 that this architecture offers at its center (between the compressor 11, the desuperheater 22, the condenser 21 and the evaporator 20) a location for integrating the possible vacuum pump 13. However, this architecture is in no way limitative and the vacuum pump can for example be below the condenser 21. Moreover, if the compressor 11 is largely included in the evaporator 20, the desuperheater 22 can be arranged at the same level, with the condenser 21 below. Compressor Lubrication and Cooling System In a conventional compressor, oil is used to cool and lubricate the compressor. The present system 1 allows the replacement of the oil with water, and generally allows even that water is the only fluid used as a thermal fluid and / or lubricating fluid. There is thus no longer any risk of contamination of refrigerant, coolant and coolant since there are more fluids than water in the system. Thus, the system advantageously comprises a lubrication circuit 40 of the compressor 11 and / or a cooling circuit 41 of the compressor 11 (preferably both), supplied with water by the thermal circuits 10, 30 and 31. The fluid of the cooling circuit 41 and / or the fluid of the lubrication circuit 40 is indeed water from a branch 300 of the cold recovery circuit 30 and / or a branch 310 of the heat dissipation circuit 31 Preferably, the cooling circuit 41 and the lubrication circuit 40 are the only lubrication / cooling circuits of the compressor 11, in other words the compressor 11 is lubricated / cooled only with water. It will be noted that the flow of water required for cooling and lubricating the compressor 11 is less than 1% of the flow of water flowing from the evaporator to the cold recovery circuit 30 or the condenser. to the heat dissipation circuit 31. If the sampling takes place on the cold recovery circuit 30 (at the outlet of the evaporator 20), the temperature will be of the order of 10 ° C. If the sampling takes place on the heat dissipation circuit 31 (at the outlet of the condenser 21), the temperature of the water taken will be of the order of 30 ° C. The flow rate taken for cooling will be lower if the water is taken from the cold recovery circuit 30. The sampling location for the lubrication and cooling of the compressor 11 has no effect on the performance of the machine. In the case where the water of the two circuits 30 and 31 is withdrawn at the same time, a three-way valve makes it possible to select a combination of the flow rates of the branches 300 and 310 so as to dynamically adjust the temperature of the water in the circuits. 40 and 41. A tapping at the return water circuit to the condenser 21 (branch 310) or a tapping at the return water circuit to the evaporator 20 (branch 300) allows to route the This water is distributed to the compressor 11 via the cooling circuit 41 and / or the lubrication circuit 40. The lubrication circuit 40 itself comprises two connections to the compressor 11. one to the suction (front part in the direction of circulation of the steam) and the other to the discharge (rear part) to ensure the lubrication of the front and rear bearings 115. The cooling circuit 40 comprises several connections, located at the back (back part E) of the compressor 11, and which cool the stator 112 and the rotor 111. The water from these two circuits 40 and 41 is then returned to the condenser 21 via the desuperheater 22. According to a second aspect the invention also relates to a method of producing cold using a heat pump system 1 according to the first aspect of the invention. The method comprises steps of: - condensation of water vapor of a main circuit 10 in a condenser 21 in heat exchange by direct contact with water of a heat dissipation circuit 31 (in particular via spraying) ; - Relaxing the liquid water in a regulator 12; vaporization of the liquid water in an evaporator in heat exchange by direct contact with water of a cold recovery circuit (typically a vapor at approximately 5 ° C. and a pressure of less than 12 millibars is obtained; even less than 9 millibars, and advantageously about 8 millibars); compression of the water vapor by an axial compressor 11 directly coupled to the evaporator 20 so as to increase the pressure of the water vapor of the main circuit 10 by at least 400% (advantageously between 500% and 700% more preferably about 600%, a compression ratio of 7. The temperature rises above 100 ° C (or up to about 270 ° C) and the pressure exceeds 50 millibars, preferably about 56 millibars); - returning the compressed steam to the condenser 21.

The last step preferably comprises the circulation of water vapor in a desuperheater 22 in heat exchange with the fluid of a heat recovery circuit 32, so as to cool the water vapor of the main circuit 10 to a temperature below 40 ° C, which as explained allows to value the temperature differential and limits the heat to be rejected via the heat dissipation circuit 31.

Claims (19)

REVENDICATIONS1. Heat pump system (1) adapted for cold production, comprising - a main circuit (10) on which are successively arranged an evaporator (20), a compressor (11), a condenser (21) and a pressure reducer (12). ); a cold recovery circuit (30); a heat dissipation circuit (31); the main circuit (10), cold recovery circuit (30) and heat dissipation circuit (31) being water circuits in the liquid and / or vapor state; the evaporator (20) putting the water of the main circuit (10) in heat exchange by direct contact with the water of the cold recovery circuit (30), the condenser (21) putting the water of the main circuit (10) ) in heat exchange by direct contact with the water of the heat dissipation circuit (31); characterized in that the compressor (11) is an axial compressor directly coupled to the evaporator (20) and configured to increase the water vapor pressure of the main circuit (10) by at least 400%. 2. System according to claim 1, wherein the compressor (11) is configured to increase the pressure of the water vapor of the main circuit (10) by a factor of between 500% and 700%. 25 The system of claim 2, wherein the compressor (11) is configured to increase the pressure of the water vapor of the main circuit (10) by about 600%. 30 4. System according to one of claims 1 to 3, configured so that the vapor pressure in the main circuit (10) is less than 12millibars input compressor (11), and greater than 50 millibars compressor output (11). ). 5. System according to claim 4, configured so that the vapor pressure in the main circuit (10) is about 8 millibars input compressor (11), and about 56 millibars output compressor (11). 6. System according to one of claims 1 to 5, further comprising a desuperheater (22) disposed on the main circuit (10) between the compressor (11) and the condenser (21), the desuperheater (22) putting the water vapor compressed from the main circuit (10) in heat exchange with the fluid of a heat recovery circuit (32). 15 7. System according to claim 6, wherein the desuperheater (22) is directly coupled to the compressor (11) and the condenser (21). 8. System according to claim 7, having the compressor (11), the desuperheater (22) and the condenser (21) stacked to a height less than the height of the evaporator (20), so that the compressor (11) ) is coupled to the evaporator (20) at an upper part of the evaporator (20), and the condenser (21) is arranged opposite a lower part of the evaporator (20). ). 25 9. System according to one of claims 1 to 8, further comprising a vacuum pump (13) connected to the condenser (21) for starting the system (1) and the regulation of operating pressure levels. 30 10. System according to claim 9, wherein the vacuum pump (13) is connected to the condenser (21) via at least one tapping at the top of the condenser (21). 11. System according to one of claims 9 and 10, further comprising a bypass circuit for the circulation of steam between the condenser (21) and the evaporator (20) when starting the system (1); 12. System according to one of claims 1 to 11, wherein the evaporator (20) comprises at least one stirrer (200) and / or at least one inclined plate (201). 13. System according to one of claims 1 to 12, wherein the heat dissipation circuit (31) comprises at least one nozzle (311) for spraying water in the condenser (21). 14. System according to one of claims 1 to 13, further comprising a lubrication circuit (40) of the compressor (11), the fluid of the lubrication circuit (40) being water from a branch (300). ) of the cold recovery circuit (30) and / or a branch (310) of the heat dissipation circuit (31). 15. System according to one of claims 1 to 14, further comprising a cooling circuit (41) of the compressor (11), the fluid of the cooling circuit (41) being water from a branch ( 300) of the cold recovery circuit (30) and / or a branch (310) of the heat dissipation circuit (31). The system of claims 14 and 15 in combination wherein water is the sole fluid used as a thermal fluid or lubricating fluid. 17. A method of producing cold using a heat pump system (1), the method being characterized in that it comprises steps of: - condensation of water vapor of a main circuit ( 10) in a condenser (21) in heat exchange by direct contact with water of a heat dissipation circuit (31); - Relaxing the liquid water in a regulator (12); - vaporizing the liquid water in an evaporator (20) in heat exchange by direct contact with water of a cold recovery circuit (30); compressing the water vapor by an axial compressor (11) directly coupled to the evaporator (20) so as to increase the pressure of the water vapor of the main circuit (10) by at least 400%; - returning the compressed steam in the condenser (21). 18. The method of claim 17, wherein the expansion is carried out to a pressure of less than 12 millibars, and the compression is carried out to a pressure greater than 50 millibars. 19. The method according to one of claims 17 and 18, wherein the step of returning the compressed steam in the condenser (21) comprises the circulation of water vapor in a desuperheater (22). heat exchange with the fluid of a heat recovery circuit (32) so as to cool the water vapor of the main circuit (10) to a temperature below 40 ° C.