FR2598789A1 - Programmable thermostatic pressure reducer - Google Patents

Abstract

The invention relates to a programmable thermostatic pressure reducer for refrigerating circuit of a heat-exchange thermodynamic machine. The pressure reducer comprises means 1 for measuring the temperature of the thermal fluid leaving the evaporator EV, and means 2 for converting the temperature measurement signal into a signal representing the fictitious saturation pressure Psur corresponding to the temperature of the superheated gas to be reached. Pressure reduction means 3 comprise a calibrated orifice 32 which can be closed by an adjustable valve 33 controlled by means 4 for converting the signal representing the fictitious saturation pressure Psur into a force. Application to the circuits of heat-exchange thermodynamic machines, such as refrigerating machines, heat pumps or the like.

Description

 The present invention relates to a programmable thermostatic expansion valve.

In thermodynamic heat exchange machine installations1 such as heat pumps and / or refrigeration units, a thermostatic expansion valve as shown in Figure la can be used to perform the following functions
- subject the thermal fluid to a loss of charge, by means of a calibrated orifice OC, in order to bring it from a state of high pressure HP to a state of low pressure BP,
- supplying a direct expansion EV evaporator while maintaining constant overheating at the outlet of the EV evaporator, the flow rate of the thermal fluid being thus regulated in the refrigeration circuit as a function of the overheating actually achieved.

It is recalled that the overheating of the thermal fluid, the latter being in the gas phase, is defined as the difference between the temperature of the fluid T and the saturated vapor temperature Tev corresponding to the pressure of the fluid Pev at the outlet of the evaporator
EV. The complete thermal cycle for an installation comprising in cascade an EV evaporator, a COM compressor, a CON condenser and a DET regulator, as represented in FIG. 1a is represented in FIG. 1b for the record.

 In order to maintain a substantially constant overheating, current systems compare two pressures, the pressure Pev of the thermal fluid at the outlet of the evaporator and the superheating pressure P representative of the overheating at the outlet of the evaporator EV. The two aforementioned pressures act antagonistically on a diaphragm ME of the regulator, which controls the opening of the calibrated orifice OC. The pressure PSUR is generated by means of an auxiliary gaseous fluid enclosed in a capsule or bulb BU in thermal contact with the outlet of the evaporator EV and whose equilibrium pressure represents a measurement of the temperature, therefore of the overheating, thermal fluid at the outlet of the EV evaporator.

 An adjustment spring RE allows the system to be calibrated according to operating parameters such as operating temperatures or overheating.

 Although satisfactory from the point of view of operation, this type of device has the drawback of an almost total absence of flexibility of use, the nature of the thermal fluid and of the auxiliary fluid being able to be chosen only from a number of very limited interdependent possibilities.

 Thus, for a given refrigeration circuit model, the couples of thermal fluid - auxiliary fluid capable of being used are very limited, and each of them can only correspond to one or to a very limited number of applications.

 The present invention aims to remedy the aforementioned drawbacks by the use of a multifunctional thermostatic expansion valve, in which the auxiliary fluid is eliminated.

 Another object of the present invention is the implementation of a thermostatic expansion valve allowing the diversified use of refrigeration circuits due to the reduction of the choice to only thermal fluid depending on the application or use considered.

 Another object of the present invention is the implementation of a thermostatic expansion valve by which the only necessary adaptation, for use for different thermal fluids, consists in switching electronic circuits.

 The programmable thermostatic regulator for the refrigerating circuit of a thermodynamic heat exchange machine object of the invention is remarkable in that it comprises means for measuring the temperature of the thermal fluid at the outlet of the evaporator, these means delivering a signal representative of this temperature.

 Means are provided for converting the signal delivered by the temperature measurement means into a signal representative, for the thermal fluid considered, of the fictitious saturation pressure corresponding to the temperature of the superheated gas to be reached. Expansion means include an intake chamber and a thermal fluid expansion chamber, the chambers being in communication via a calibrated orifice concealable by an adjustable valve. The valve is controlled by a movable element actuated by means for converting the signal representative of the fictitious saturation pressure into force.

 The invention finds application in the industry of thermodynamic heat exchange machines for the production of heat pumps or refrigeration machines in particular.

It will be better understood on reading the description and on observing the drawings below in which
the fiours la and lb relating to the prior art represent a conventional thermostatic regulator and a Mollier diagram relating to a circuit of a heat exchange heat machine comprising such a regulator,
FIG. 2 represents a block diagram of the programmable thermostatic regulator object of the invention,
FIG. 3 represents a particular advantageous embodiment of the programmable thermostatic expansion valve object of the invention, as shown in FIG. 2,
- Figure 4 shows another particular advantageous embodiment of the most mostatic programmable regulator object of the invention.

 - Figure 5 shows a preferred embodiment of means for transcoding a signal representative of the temperature of the thermal fluid, at the outlet of the evaporator EV, into a signal representative of the fictitious saturation pressure Psur.

 The operation of a conventional regulator as shown in Figure la will first be briefly recalled in relation to the Mollier diagram shown in Figure lb. On the diagram of FIG. 1b, the abscissa axis is graduated in enthalpy, denoted H, and the ordinate axis in logarithm of the pressure of the thermal fluid.

 The regulator, as represented in FIG. 1a, ensuring the connection between the outlet of the condenser and the inlet of the evaporator, these points in FIG. 1b being noted respectively outlet CON and inlet EV, the latter in fact makes it possible to ensure isenthalpic or constant energy expansion of the thermal fluid passing through it. Thus, the expansion valve in fact ensures, on the one hand, a pressure drop ss P between the high pressure HP of the fluid and the low pressure BP of the latter, and on the other hand, a supply of the evaporator with flow of thermal fluid compatible with the characteristics of a cold source.

 Of course, the programmable thermostatic expansion valve, object of the invention, ensures an operation similar to that shown in Figure la.

 As it appears in FIG. 2, the programmable thermostatic expansion valve which is the subject of the invention is remarkable in that it comprises means denoted 1, for measuring the temperature of the thermal fluid at the outlet of the evaporator EV. The means 1 for measuring the temperature of the thermal fluid can be constituted by a thermometric probe such as a platinum resistor, for example, placed at the outlet of the body of the evaporator in close contact with the fluid. A detailed assembly of this type of element will not be described since the use of it is entirely conventional. The means for measuring the temperature of the thermal fluid delivers an analog type signal representative of the temperature of this fluid.

 In addition, means 2 for converting the signal delivered by the temperature measurement means are provided to generate a signal representative, for the thermal fluid considered, of the fictitious saturation pressure Psur corresponding to the temperature of the superheated gas to be reached.

 Expansion means 3 comprising an inlet chamber 30 and an expansion chamber 31 of the thermal fluid are further provided, the inlet chamber 30 being of course supplied with high pressure thermal fluid HP. The inlet 30 and expansion 31 chambers are in communication via a calibrated orifice 32, concealable or adjustable by an adjustable valve 33. The valve 33 is itself controlled by a movable element 34 actuated by the intermediate of means 4 for converting the signal representative of the fictitious saturation pressure Psur into force. In Figure 2, there is simply shown the movable member 34 by a dashed line connecting the valve 33 and the conversion means 4. A more detailed description of this movable member will be given later in the description.

 The operation of the thermostatic regulator, object of the invention, is as follows. Upon detection of the temperature of the thermal fluid leaving the evaporator 2b, the conversion means allow the corresponding determination of the fictitious saturation pressure Psur corresponding to the temperature of the superheated gas to be reached, the value of the corresponding signal allowing by the intermediate the conversion means 4 the adjustment accordingly of the valve 33 and therefore of the pressure drop 4P between the inlet chamber 30 and the expansion chamber 31, as well as the flow of fluid supplying the evaporator EV.

 According to a particular embodiment of the means 4 for converting the signal representative of the fictitious saturation pressure Psur into force, represented in FIG. 3, these means can comprise, for example, a voltage amplifier 43 receiving the analog signal representative of the pressure Psur, this amplifier being intended to power a stepping motor 40, the motor shaft 401 of which is connected by means of a mechanism to the movable element 34 controlling the adjustable valve 33. By way of nonlimiting example, the motor 40 may be constituted by a direct current motor or a stepping motor associated with a torque reducer denoted 400. The aforementioned mechanism may consist of a spring system 402, which, by means of two stop rings 403 and 404 , allows the transmission of the movement of the motor shaft 401 to the mobile element 34 and the transformation of this movement into a translational movement of the mobile element 34, allowing the adjustment in position of the valve. adjustment pe 33. In FIG. 3, it will be noted that the part B of the regulator shown may advantageously consist of a regulator normally available commercially and marketed by the company DANFOSS, under the reference PHT 85, the upper part of this conventional regulator being deleted and replaced by part A as previously described and shown in FIG. 3.

Another particularly advantageous embodiment of the means 4 for converting the signal representative of the imaginary saturation pressure
Psur en force, will now be described in conjunction with Figure 4.

 In this figure, there is shown in B, schematically, a regulator body substantially similar to part B constituting the regulator body of Figure 3. Of course, in the case of Figure 4, a regulator of the same type as that mentioned in the case of Figure 3, can be used.

The conversion means 4 then comprise a pressure generator 41 controlled by the signal representative of the pressure Psur, this pressure generator being connected to the supply orifice 410 of a piston body 420, comprising a movable piston 42 controlled in pressure by the pressure generator 41. The mobile piston 42 is of course mechanically coupled to the adjustable valve 33. It will be understood that in this case, the counter-pressure chamber of the piston 42 being connected to atmospheric pressure by a port 421, the pressure control of the piston 42 by the pressure generator 41 enables operation similar to the device as shown in FIG. 3 to be ensured.

 By way of nonlimiting example, the pressure generator 41 can be constituted by a hydraulic cylinder.

 In all cases, the control of the stepping motor or of the pressure generator can advantageously be carried out by means of a derivative proportional inigrab control circuit, circuit P. r. D.

 A particularly advantageous embodiment of the means for converting the signal delivered by the temperature measurement means 1 into a signal representative, for the thermal fluid considered, of the fictitious saturation pressure Psur will be described in connection with FIG. 5.

According to this figure, the aforementioned conversion means comprise transcoding means denoted 500, values of the signal representative of the temperature in fictitious saturation pressure values
Psur.

 As it further appears in FIG. 5, the transcoding means 500 can comprise means 501 of analog-digital conversion of the signal delivered by the temperature measurement means 1, and storage means, denoted 502, of values of saturation pressure Psur. The saturation pressure values Psur can for example be stored at addresses corresponding to the digital values delivered by the analog-to-digital conversion means 501, as a function of the value of the analog input signal delivered by the means for temperature measurement. Thus, for a determined value of the analog signal delivered by the thermometric probe 1, the corresponding digital value obtained after analog-to-digital conversion via the analog-to-digital converter 501, allows direct reading of the storage means 502 at the corresponding address. and obtaining at the output of the storage means 502, a digitized signal representative of the pressure Psur.

 In addition, and advantageously, the transcoding means 500 can comprise digital-analog conversion means 503, receiving the digital value representative of the pressure Psur delivered by the storage means 502, and making it possible to generate an analog signal representative of the pressure Psur, authorizing the control of the conversion means 4.

 Advantageously, the storage means 502 consist of an EPROM type read only memory. In fact, it will be understood, in accordance with an essential advantage of the object of the invention, that the storage means can in fact be constituted by a plurality of read-only memories of EPROM type, these memories being for example switchable or interchangeable, and corresponding to a specific thermal fluid.

 Thus, for an evaporation temperature of the thermal fluid denoted Tev and an overheating of 50C for example, the thermometric probe 1 indicates a temperature T at the outlet of the evaporator EV, after the overheating. The value read at the address corresponding to this signal is then the fictitious saturation pressure Psur of the thermal fluid at the temperature of T - 5 C. This pressure is then exerted on the piston 42 for example, by the pressure generator 41.

 In the case where T is lower than the normal operating temperature, ie Tev + 50C, then the pressure Psur, corresponding to T - 50C, is lower than the pressure in the chamber 35 (cf. Fig. 4).

The valve 36 closes the communication between the chamber 36 and the low pressure upper part. Thus the Medium Pressure MP in the chamber 37 increases due to the presence of small channels 38 between the High
Pressure EP and the Medium Pressure, M P. and the calibrated orifice 32 closes by means of the valve 33. The thermal fluid flow decreases and as the power supplied to the evaporator is constant, the overheating increases, this which is the desired effect.

In the case where on the contrary the temperature
T is greater than the normal operating temperature, ie Tev + 50C, the pressure Psur, corresponding to T - 50, is then greater than the pressure in the chamber 35. In this case, the valve 36 lowers and the average pressure MP in room 37 decreases.

 Thus, the calibrated orifice 32 opens, via the valve 33, the flow of thermal fluid increases and as the power supplied to the evaporator is constant, the overheating decreases.

 A particularly advantageous programmable holder has thus been described in that, by a single change or switching, suitable for memory 502, this allows, while keeping the same body of relaxation and without any mechanical modification, to immediately adapt the holder, object of the invention, in any new thermal fluid, or non-azeotropic mixture, if the characteristics of this are known. The programmable holder which is the subject of the invention also makes it possible, advantageously, to choose the desired overheating. In addition, the object holder of the invention remains usable with very high precision over any range of temperatures.

Claims (9)

 1. Programmable thermostatic expansion valve for the refrigeration circuit of a thermodynamic heat exchange machine, characterized in that it comprises  means (1) for measuring the temperature of the thermal fluid leaving the evaporator (EV), said means (1) delivering a signal representative of said temperature,  means (2) for converting said signal delivered by temperature measurement means into a signal representative, for the thermal fluid considered, of the fictitious saturation pressure (Psur) corresponding to the temperature of the superheated gas to be reached,  - regulator means (3) comprising an inlet chamber (30) and an expansion chamber (31) of the thermal fluid, the chambers being in communication via a calibrated orifice (32) concealable by an adjustable valve (33), said valve being controlled by a movable element (34) actuated by means for converting (4) the signal representative of the fictitious saturation pressure (Psur) into force.  2. Device according to claim 1, characterized in that the means (1) for measuring the temperature of the thermal fluid at the outlet of the evaporator are constituted by a thermomotor probe.  3. Device according to one of claims t or 2, characterized in that said means for converting the signal representative of the fictitious saturation pressure (Psur) corresponding to the temperature of the gas superheated by force comprises  a voltage amplifier receiving the analog signal representative of the pressure (Psur), said amplifier supplying  - a stepping motor (40) whose motor shaft (401) is connected, by means of a mechanism, to the movable element (34) controlling the adjustable valve (33).  4. Device according to one of claims 1 or 2, characterized in that said means for converting the signal representative of the fictitious saturation pressure (Psur) corresponding to the temperature of the superheated gas comprise:  a pressure generator (41) controlled by said signal representative of the pressure (Psur),  - a mobile piston (42) controlled by said pressure generator (41), said mobile piston (42) being mechanically coupled to said adjustable valve (33).  5. Device according to one of claims 3 or 4, characterized in that the control of the stepping motor or of the pressure generator is carried out by means of a derivative integral proportional control circuit (P.I.D.).  6. Device according to claim 4, characterized in that said pressure generator is constituted by a hydraulic cylinder.  7. Device according to one of the preceding claims, characterized in that the means for converting the signal delivered by the temperature measurement means into a signal representative, for the thermal fluid considered, of the fictitious saturation pressure (Psur) comprise means for transcoding (500) the values of the signal representative to the temperature into fictitious saturation pressure values (Psur).  8. Device according to claim 7, characterized in that said transcoding means (500) comprise  - means (501) for the analogue analog conversion of the signal delivered by the temperature measurement means,  - means (502) for storing saturation pressure values (Psur), said saturation pressure values (Psur) being stored at addresses corresponding to the digital values provided by said analog-to-digital conversion means as a function of the value of the analog input signal delivered by the temperature measurement means.  9. Device according to claim 8, characterized in that said storage means are constituted by one or more read only memories of EPROM type, said memories being switchable and corresponding to a specific refrigerating fluid.