FR2851795A1 - Hydraulic pump comprises pump piston driven in pumping cylinder by drive piston moved in driving cylinder by high expansion coefficient liquid, tube bundle undergoing thermal exchange with heat and cold sources connected to drive chamber - Google Patents

Abstract

The hydraulic pump (45) comprises a pumping piston (21) is driven in a pumping cylinder (20) by a driving piston (28) moved in a driving cylinder (27) by a liquid (10) with a high expansion coefficient. The pumping piston is enclosed in a closed chamber constituted by a driving chamber (29) of the drive cylinder. A tube bundle (32) has thermal exchange alternatively with a heat source (4) and with a cold source (5). A hydraulic connecting conduit (31) connects the driving chamber and the tube bundle. An independent claim is included for a hydraulic installation comprising a hydraulic pump.

Description

Hydraulic pump and hydraulic installation comprising such a pump

  The present invention relates to a hydraulic pump of the type comprising, in at least one example: - a pumping cylinder and a pumping piston mounted to slide in the pumping cylinder and delimiting there a sealed pumping chamber, - hydraulic connection means between a hydraulic fluid reservoir and the pumping chamber, comprising non-return means passing towards the pumping chamber, - hydraulic connection means between the pumping chamber and means consuming hydraulic fluid, comprising anti-friction means passers-by return to the consumer means, and - motor means for driving the pumping piston in an alternating sliding movement in the pumping cylinder.

  It is more particularly interested in the possibility of motorizing such a pump under conditions in which, for reasons of implantation, for example in isolated or desert areas, the use of an electric or thermal motor for this purpose is excluded or when such use is deliberately excluded for reasons of economy or ecology.

  To meet such conditions or such a choice, the present invention provides a pump of the type indicated in the preamble, characterized in that the driving means comprise: - a driving cylinder and a driving piston mounted to slide in the driving cylinder and there delimiting a sealed motor chamber, - kinematic connection means between the driving piston and the pumping piston, so that an increase in volume of the motor chamber corresponds to a reduction in volume of the pumping chamber and vice versa, - a hydraulic connection pipe between the driving chamber and a tubular heat exchange bundle, forming with the pipe and with the driving chamber a closed enclosure, - a liquid with a high coefficient of thermal expansion, enclosed in said closed enclosure and filling it , and - means for placing the tube bundle in heat exchange relation alternately with a hot source and with a e cold spring.

  A person skilled in the art will readily understand that such a pump according to the invention makes it possible to solve the problems associated with the exploitation of thermodynamic solar cold by replacing the electric motor 25 generally chosen to drive the compressor of a refrigerating machine with a motor. hydraulic, then constituting the means consuming hydraulic fluid, which in particular makes it possible to use solar energy, as a hot source, to produce cold in an air conditioning system, the energy demand of which is higher when there is a lot of sun, that is to say precisely at times when we can have more solar energy.

  However, the power of a hydraulic motor thus supplied by a pump according to the invention can also be used to assist a heat engine by using the thermal energy of the coolant of this engine. In such an application, the heat of the coolant of the heat engine is converted into hydraulic pressure by the pump according to the invention, and the hydraulic motor m by this pressure makes it possible to lighten the task of the heat engine and to allow it to consume less polluting fuel or, in the case of a refrigerated vehicle, run the compressor thereof. The application on a boat can be interesting because the cold source can then be in the flotation water.

  A hydraulic motor powered by a pump according to the invention can also control a generator 20 in the presence of geothermal resources, or in any place of heat production such as the food industry, for example for the production of cold necessary to the conservation of food at the end of production lines, or even near nuclear power plants, which produce a lot of recyclable hot water before being evacuated to the rivers.

  The hydraulic energy supplied by the pump according to the invention can also be used to directly drive the piston of a compressor in an air conditioning installation.

  These application examples are however in no way limiting and, in particular, provision can also be made to use a hydraulic pump according to the invention to perform underground pumping for the purpose of supplying, for example, irrigation installations, or to practice cutting parts with pressurized water.

  In general, as an example of a hot source, mention may be made of solar radiation, the cooling circuits of heat engines or condensers, industrial discharges, geothermal energy, electric heating, and, by way of examples. from a cold source, mention may be made of ambient air, if necessary forced by a fan, running water, the heating circuits of an evaporator, these examples being in no way limiting.

  It will be observed that the hot or cold sources necessary to operate the pump according to the invention when it is intended to supply energy to a refrigerating machine or a heat pump can be borrowed in part from these machines, since the condenser and the aforementioned evaporator may respectively form an integral part of the refrigerating machine or the heat pump, which makes it possible, in particularly hot or particularly cold countries, to operate such a refrigerating machine or such a heat pump with little or no non-renewable energy, allowing almost free energy production from air conditioning.

  So that the thermal expansions and alternating thermal contractions of the liquid with a high coefficient of thermal expansion allow to develop as large an energy as possible, one preferably chooses such a liquid having a coefficient of thermal expansion at least equal to 5 1/1000 per OC , and for example a liquid chosen from a group comprising anhydrous alcohol and fuel oil. These examples are however in no way limitative since the liquid chosen makes it possible to develop, by its expansion, an energy high enough to be usable, if necessary by coupling in parallel several pumps according to the invention, that is to say by connecting the corresponding hydraulic connection means in parallel, comprising the corresponding return means, respectively between the tank and the pumping chambers and between the pumping chambers and the consumer means, it being understood that, moreover, depending on the applications envisaged for the pump, the drive chamber and the drive piston may have a smaller cross-section than that of the pumping chamber and the pumping piston.

  According to a particularly economical embodiment, in this case, provision is preferably made for the driving piston and the pumping piston to be constituted by two stages of the same differential piston 25 and for the driving chamber and the pumping chamber to be constituted by two chambers, mutually aligned and separated from each other by the differential piston, of the same cylinder constituting the driving cylinder and the pumping cylinder.

  In other applications, however, the driving chamber and the driving piston could have a cross section identical to, or even greater than, that of the pumping chamber and the pumping piston.

  It will be observed that the connection of several pumps according to the invention in parallel, accompanied by a phase shift between the different pumps, allows the hydraulic pressure obtained to be smoothed to a certain extent when desired. However, for this purpose, in addition or as a replacement, it is also possible to provide that the consuming means comprise an accumulator 10 of hydraulic pressure, interposed between them and the means of hydraulic connection between the pumping chamber and them, which makes it possible to supplying the consumer means proper with hydraulic energy at a substantially constant pressure despite the reciprocating movement of the or each pumping piston.

  The pumping chamber, the corresponding hydraulic connection means, comprising the corresponding non-return means, the reservoir and the consuming means constitute in certain applications an open circuit, as is the case when the hydraulic pump according to the invention is used for to draw water. However, in all the applications in which this is possible, and in particular when the pump according to the invention is intended to supply a hydraulic motor, it is preferred that the pumping chamber, the corresponding hydraulic connection means, comprising the anti-friction means - corresponding return, the reservoir and the consumer means, including the possible hydraulic pressure accumulator, 30 constitute a closed circuit in which, thus, the nature and cleanliness of the hydraulic fluid are fully controlled.

  Various means can be chosen to place the tubular bundle in heat exchange relationship 5 alternately with the hot source and with the cold source and, in particular, provide a fixed tubular bundle on which, alternatively, a flow of liquid is caused heat transfer medium from the cold source and a flow of heat transfer liquid from the hot source.

  However, the use of such an alternating flow slows down the operating cycle of the pump according to the invention, and the alternating presence of a hot heat-transfer liquid and a cold heat-transfer liquid in the same enclosure results in losses of significant energy, and it is preferred to make the means for placing the tube bundle in heat exchange relationship alternately with the hot source and with the cold source in a form comprising: - a tank divided by a horizontal partition, thermally insulating , in a lower chamber and an upper chamber, - means for circulating a heat transfer liquid between the lower chamber and the cold source, - means for circulating a heat transfer liquid between the upper chamber and the hot source, and - means for moving back and forth vertically, inside the tank, the tubular bundle, comprising at least one copy of a vertical tube passing freely through the partition n by a corresponding orifice, between a high position, in which it bathes in the upper chamber, and a low position, in which it bathes in the lower chamber.

  In a particularly simple manner, the means for moving the tubular beam back and forth vertically comprise a hydraulic cylinder and controlled distributor means for supplying the cylinder with hydraulic liquid, which advantageously comes from the reservoir in the case in which the chamber pump, the corresponding hydraulic connection means, comprising the corresponding non-return means, the tank and the consuming means, including the possible hydraulic pressure accumulator, constitute a closed circuit in which the hydraulic fluid in the tank retains a pressure sufficient to be so used.

  Of course, other means could also be used for this purpose without departing from the scope of the present invention.

  Insofar as, as deduced from the above, a pump according to the invention generally does not only serve to supply energy to the consuming means but can cooperate with them more fully, the present invention also extends to an installation comprising a hydraulic pump according to the invention, associated with a hydraulic fluid reservoir and with means consuming hydraulic fluid, in particular chosen, by way of nonlimiting example, from a group comprising the hydraulic motors and the hydraulically driven compressors, in particular as components of air conditioning systems.

  Other characteristics and advantages of the various aspects of the present invention will emerge from the description below, relating to a nonlimiting example, as well as from the appended drawings which accompany the present invention.

  The single FIGURE schematically illustrates an installation using a hydraulic pump according to the invention, comprising three pumping pistons and used for supplying, in hydraulic fluid 10 circulating in closed circuit, a hydraulic motor such as a motor with gear.

  It is understood, however, that a pump according to the invention could also comprise a single pumping piston, or any other desired number of pumping pistons, and have applications other than supplying a hydraulic motor with hydraulic fluid, as previously indicated.

  The hydraulic pump according to the invention has been designated by 45, which comprises, in the same body not shown or in separate respective bodies also not shown, three stepped non-referenced cylinders each of which group, aligned along the same longitudinal axis, a driving cylinder 27 and a pumping cylinder 20 which has a greater cross section, and preferably much greater, for example in a ratio of 10 to 1, than that of the driving cylinder 27. In each of these cylinders 27 and 20 is mounted in longitudinal sliding, a transverse piston of respective corresponding section, namely a driving piston 28 delimiting inside the driving cylinder 27 a driving chamber 29 and a pumping piston 21 delimiting in the pumping cylinder 20 a pumping chamber 22. The two pistons 28 and 21 thus associated are rigidly linked together by means shown diagrammatically at 30, for example due to a r alisation in the form of two stages of the same differential piston separating from one another the chambers 29 and 22, mutually aligned, so that the longitudinal sliding of the differential piston in one direction corresponds to an increase in volume of one of these chambers and a simultaneous reduction in the volume of the other chamber, and vice versa.

  Such longitudinal sliding of the differential piston, grouping the driving piston 28 and the pumping piston 21, are caused in accordance with the present invention by means of a liquid 10 with a high coefficient of thermal expansion, for example at least equal to 1 in 1000 per degree Celsius, such as anhydrous alcohol or fuel oil, filling a closed enclosure of which the motor chamber 29 is a part and which is introduced or extracted therefrom by motor means 26 which are characteristic of the present invention and will be described later, to animate the driving piston 28 and, with it, the pumping piston 21 with a reciprocating longitudinal sliding movement in the respective cylinder 27, 20, so as to cause, by the alternating variations in volume of the pumping chamber 22 which results therefrom, the pumping of a hydraulic liquid 11 which, depending on the applications, may be of a different nature.

  Thus, in the illustrated application in which it is a question of supplying a hydraulic motor 7, the liquid 11 advantageously consists of a hydraulic oil of known type whereas, in other applications, it could be water, as would be the case for example in an application for raising water for irrigation purposes or in an application for cutting water parts, these examples being in no way limiting .

  In the example illustrated, the hydraulic fluid 11 evolves in a closed circuit comprising: - a reservoir 6 maintained at a pressure higher than atmospheric pressure and for example of the order of 2 bars, which will be considered as low pressure in comparison with the other pressures used,

  as will emerge from the following description,

  a pipe 23 for hydraulic connection between the tank 6 and the pumping chamber 22, this pipe 23 comprising a non-return valve 24 passing towards the pumping chamber 22, this pumping chamber 22, a pipe 25 going from this room pumping 22 towards the hydraulic motor 7, this pipe 25 comprising a non-return valve 16 passing towards the hydraulic motor 7, - a hydraulic accumulator 8 which is preferably provided and which is interposed in the pipe 25 between the valve non-return 16 and the hydraulic motor 7 and is brought to a pressure higher than that of the tank 6 and considered to be average in comparison with the other pressures implemented by the device, and for example of the order of 200 bars , - an unreferenced pipe returning the hydraulic motor 7 to the tank 6, comprising a non-return valve 46 passing towards this tank 6 and, between the non-return valve 46 and the tank 6, a limit ur of 5 pressure 13 set to the low pressure which it is desired to have in the tank 6, namely 2 bars in the numerical example chosen.

  Another pressure relief valve 12, set to the medium pressure which it is desired to have in the accumulator 8, namely 200 bars in this digital example, is provided in a bypass starting from the pipe 25 between the non-return valve 16 and the pressure accumulator 8 and terminating between the non-return valve 46 and the pressure limiter 13.

  Naturally, in an application of the pump according to the invention 45 to an elevation of water for example for irrigation purposes, the reservoir 6 could be constituted for example by the groundwater or by a tarpaulin and the pipe 25 could be '' open freely during use, without pressure accumulator 8 or return to the water table or tarpaulin serving as a reservoir 6. Line 25 could also open freely for use in other applications, such as water cutting.

  When, as illustrated, the pump 45 according to the invention comprises several pumping chambers 22, these are connected in parallel, by means of respective non-return valves 16 and 24 and respective branches of the pipes 23 30 and 25 between the reservoir 6 and the pressure accumulator 8 or, in the absence thereof, the means consuming hydraulic fluid 11, here constituted by the hydraulic motor 7.

  On the other hand, it is independently of one another that the drive chambers 29 are part of a respective closed enclosure 5 filled with hydraulic liquid 10 with a high coefficient of thermal expansion, serving as the working fluid, the differential pistons each consisting a driving piston 28 and a pumping piston 21 which can thus be controlled in synchronism, as illustrated for the two lower differential pistons, or in phase opposition, as illustrated for the two superior differential pistons, or alternatively according to any desired sequencing according to the envisaged application, as will readily be understood by a person skilled in the art.

  The closed enclosure to which each of the drive chambers 29 respectively belongs is further constituted by a respective tubular bundle 32 of heat exchange, an embodiment of which will be detailed below, and by a respective pipe 31 for hydraulic connection between this heat exchanger 32 and the driving chamber 29. In this pipe 31 is interposed a pressure limiter 9 set to a comparatively high pressure, for example of 2000 bars, the liquid with a high coefficient of thermal expansion present in the closed enclosure constituted through the chamber 29, the pipe 31 and the corresponding heat exchanger 32 respectively which can be brought to even higher pressures, according to which the materials constituting these various components must be chosen. Thus, by way of nonlimiting example, it is possible to choose, for producing the heat exchanger 32, beryllium copper or certain molybdenum alloys, which have both sufficient mechanical strength and good thermal conductivity; the pipe 31, at least partially flexible for reasons which will appear later, must also be made of a material capable of withstanding the pressures brought into play in the liquid 10 with a high coefficient of thermal expansion.

  According to the preferred embodiment which has been illustrated, each heat exchanger 32 consists of a bundle of vertical tubes, for example with a length of 700 mm for an inside diameter of 2 mm and an outside diameter of 6 mm, by example on the basis of 12 15 rows of 20 tubes 43 closed at their lower end and communicating with each other, at their upper end, by a manifold into which the pipe 31 opens and which also ensures mutual mechanical connection of the tubes 43.

  Each of the tubular heat exchange bundles 32 thus formed is placed inside a respective tank 33, divided by a horizontal thermally insulating partition 34, pierced with as many orifices 44 as there are tubes 43, so that each tube 43 25 passes right through the partition 44 through an orifice 44 respectively corresponding under conditions suitable for ensuring as good a seal as possible between the partition 34 and each tube 43.

  The partition 34 subdivides the corresponding tank 33 30 into a lower chamber 35 and into an upper chamber 36 containing a respective heat transfer liquid 41, 42 which may be of the same nature, and for example be water.

  The lower chamber 35 or, when several are provided, as is the case in Example 5 illustrated, the different lower chambers 35, in parallel, are connected, by a pipe 37 for the supply of heat-transfer liquid and by a pipe 38 for starting the heat transfer liquid, to a cold source 5 which may be of any of the aforementioned types, or else of another type, and which makes it possible to circulate the heat transfer liquid 41, which is comparatively cold, in the lower chamber 35. Likewise, the upper chamber 36 or, when several are provided, each of the upper chambers 36, in parallel, is connected to a hot source 4 by an inlet pipe 39 and a return pipe. flow 40, which makes it possible to circulate the heat transfer liquid 42, comparatively hot, in the or each upper chamber 36. The hot source 4 can be of any one of the aforementioned types, or else of a different type.

  In order to place each tube bundle 32 alternately in heat exchange relationship with the cold heat transfer fluid 41 and with the hot heat transfer fluid 42, means are provided for moving each tube bundle 32, here independently of one another, vertically back and forth inside the tank 33 respectively corresponding, between a high position, in which this tubular bundle 32 bathes almost entirely in the hot liquid 42 inside the upper chamber 36, only the ends lower tubes 43 still being engaged in the orifices 44 of the partition 34, as is the case of the tubular bundle 32 illustrated on the left of the figure, and a low position, illustrated with regard to the two tubular bundles situated to the right of the FIG. 5 in which the tubular bundles 32 are almost entirely immersed in the heat transfer liquid 41 inside the lower chamber 35, only the adhesive cteur, suitably thermally insulated, then being placed above the partition 34. The two tubular bundles 32 illustrated in the right part of the figure, thus placed in contact with the cool coolant 41, correspond to the motor chambers 29, having their minimum volume, of the two lower cylinders while the tubular bundle 32 situated on the left of the figure, immersed in the hot heat-transfer liquid 42, corresponds to the motor chamber 29, having its maximum volume, of the upper cylinder.

  To move thus back and forth vertically each of the tubular bundles 32 inside the tank 20 corresponding respectively, between the high position and the low position, are provided jacks 15 each of which is associated with one, respective , tubular bundles 32 and is arranged above the corresponding tank 33.

  Each of the jacks 15 is vertical and internally comprises a horizontal piston 52 connected to the collector of the tube bundle 32 respectively corresponding by a vertical rod 50.

  Inside each cylinder 15, the corresponding piston 30 separates two chambers 53, 54 each of which is connected, by a respective pipe 48, 49, to a hydraulic distributor 14 making it possible to introduce in a controlled manner, alternately to the inside the chamber 54 and inside the chamber 53 of each jack 15, leaving the other chamber thereof to the exhaust, a hydraulic fluid which may be different from the hydraulic fluid 11, in particular when the conditions of application of the pump according to the invention 45 do not allow the fluid 11 to be used to supply the jacks 15, but which, in the example illustrated, consists of this fluid 11, brought to the distributor 14, from the tank 6, by a pipe 47 for example connected to one of the pipes 23, between the tank 6 and the corresponding non-return valve 24.

  The distributor 14, the embodiment 15 and control of which is within the normal abilities of a person skilled in the art, can be programmed to cause in phase, in phase opposition or with a determined phase shift back and forth movements. comes vertically from the different tubular heat exchange bundles 32 inside the tanks 33 to cause thermal expansions and alternating thermal contractions of the liquid 10 with a high coefficient of thermal expansion in the different tubes of each tubular bundle 32, depending on whether tubular bundle bathes in the hot liquid 42 or in the cold liquid 41, which respectively causes the supply of the corresponding chambers 29 with hydraulic liquid 10, that is to say the increase in the volume of these chambers 29 to the detriment from that of the chambers 22 which expel the hydraulic fluid 11 to the pressure accumulator 8 and the hydraulic motor 7 then, in return, to the reservoir 6 in the case of the illustrated application, and a reduction in the volume of the corresponding chambers 29 with the increase in the volume of the corresponding chambers 22, which causes the suction of hydraulic fluid 11 from 5 from the reservoir 6, the alternation of these suction and discharge phases causing the desired pumping effect.

  The changes of state of the distributor 14, for this purpose, can advantageously be brought about, automatically, under the control of end-of-travel detectors excited by the arrival of each tube bundle 32 respectively in the high position and in the low position, by the fluid 11 itself when this fluid is used to supply the jacks 15. Other means 15 can however be used for this purpose, it being understood that preferably means which will be chosen, such as those which have just be described, draw their energy from the installation itself, that is to say ensure that it has operating autonomy. Generally, a person skilled in the art will readily understand that, just as

  the illustrated and described application of a pump according to the invention 45 constitutes only a nonlimiting example, the constitution of this pump 45 itself as well as that of its motor means 26 25 could have many variants, in particular according to the 'chosen application, without departing from the scope of the present invention.

Claims (14)

  1. Hydraulic pump of the type comprising, in at least one copy: - a pumping cylinder (20) and a pumping piston 5 (21) slidably mounted in the pumping cylinder (20) and delimiting there a sealed pumping chamber (22), - means (23) for hydraulic connection between a reservoir (6) of hydraulic liquid (11) and the pumping chamber (22), comprising non-return means (24) 10 passing to the pumping chamber (22), - means (25) for hydraulic connection between the pumping chamber (22) and means (7) consuming hydraulic fluid (11), comprising non-return means (16) passing to the consuming means (7) , 15 and - motor means (26) for driving the pumping piston (21) with an alternating sliding movement in the pumping cylinder (20), characterized in that the motor means (26) 20 comprise: - a engine cylinder (27) and an engine piston (28) slidably mounted in the engine cylinder (27) and delimiting therein sealed motor chamber (29), - means (30) for kinematic connection between the motor piston (28) and the pumping piston (21), so that an increase in volume of the motor chamber (29) corresponds a reduction in volume of the pumping chamber (22) and vice versa, - a pipe (31) for hydraulic connection between the driving chamber (29) and a tubular heat exchange bundle (32), forming with the pipe ( 31) and with the driving chamber (29) a closed enclosure, - a liquid (10) with a high coefficient of thermal expansion, enclosed in said closed enclosure and filling it, and - means for placing the tube bundle (32) in heat exchange relationship alternately with a hot source (4) and with a cold source (5).   2. Pump according to claim 1, characterized in that the driving chamber (29) and the driving piston (28) have a smaller section than that of the pumping chamber (22) and the pumping piston (21).   3. Pump according to claim 2, characterized in that the driving piston (28) and the pumping piston (21) consist of two stages of the same differential piston, and the driving chamber (29) and the pumping chamber (22) by two chambers, mutually aligned and separated from each other by the differential piston, of the same cylinder constituting the driving cylinder (27) and the pumping cylinder (20).   4. Pump according to any one of claims 1 to 3, characterized in that the consumer means (7) comprise an accumulator (8) of hydraulic pressure, interposed between them (7) and the hydraulic connection means (25) between the pumping chamber (22) and them (7).   5. Pump according to any one of claims 1 to 4, characterized in that the pumping chamber (22), the corresponding hydraulic connection means (23, 25), comprising the non-return means 5 (24, 16) corresponding, the reservoir (6) and the consumer means (7) constitute a closed circuit.   6. Pump according to any one of claims 1 to 5, characterized in that the means 10 for placing the tube bundle (32) in heat exchange relation alternately with the hot source (4) and with the cold source (5 ) comprise: - a tank (33) divided by a horizontal partition (34), thermally insulating, into a lower chamber (35) and an upper chamber (36), - means (37, 38) for circulation of a heat transfer liquid (41) between the lower chamber (35) and the cold source (5), - means (39, 40) for circulation of a heat transfer liquid (42) between the upper chamber (36) and the hot source (4), and - means (14, 15) for moving back and forth vertically, inside the tank (33), the tubular bundle (32), comprising at least one copy of a tube vertical (43) freely passing through the partition (34) through a corresponding orifice (44), between a high position, in which it is immersed in the upper chamber, (36) and u does not lower position, in which it bathes in the lower chamber (35). 30 7. Pump according to claim 6, characterized in that the means (14, 15) for moving the tubular bundle (32) back and forth vertically comprise a hydraulic cylinder (15) and 5 controlled distributor means (14) supplying the cylinder (15) with hydraulic fluid (11).   8. Pump according to claim 7 in its dependency relation vis-à-vis claim 5, 10 characterized in that the controlled distributor means (14) supply the cylinder (15) with hydraulic liquid (11) from the reservoir (6 ).   9. Pump according to any one of claims 1 to 8, characterized in that said coefficient of thermal expansion is at least equal to 1/1000 per OC.   10. Pump according to claim 9, characterized in that the liquid with a high coefficient of thermal expansion is chosen from a group comprising anhydrous alcohol and fuel oil.   11. Pump according to any one of claims 1 to 10, characterized in that the hot source (4) is chosen from a group comprising solar radiation, cooling circuits of heat engines or condensers, industrial discharges, geothermal or other.   12. Pump according to any one of claims 1 to 11, characterized in that the cold source (5) is chosen from a group comprising ambient air, running water, the heating circuits of an evaporator or the like.   13. Hydraulic installation, comprising - a hydraulic pump, - a reservoir (6) of hydraulic fluid (11), - means (7) consuming hydraulic fluid (11), characterized in that the hydraulic pump (45) conforms to any of claims 1 to 12.   14. Hydraulic installation according to claim 13, characterized in that the means (7) consuming hydraulic fluid are chosen from a group comprising hydraulic motors and compressors driven hydraulically, in particular as components of air conditioning installations.