FR2725778A1 - PILOT AIR CONDITIONER BY A DEVICE PROVIDING A MEASURE RELATING TO THE REFRIGERANT FLUID USED - Google Patents

Abstract

Air conditioner comprising in particular an air cooler evaporator (1 '), an air condenser (2') and a compressor (3 ') connected in a loop by a circuit in which a refrigerant circulates and where the admission of this fluid from the condenser by the evaporator is controlled by an expansion valve (9 ') inserted between this condenser and this evaporator and controlled from at least one device providing a measurement, relating to the fluid, carried out in a determined zone of the circuit. The air conditioner comprises at least one heat flowmeter (18 '), positioned in a determined zone of the circuit, to at least partially control the expansion valve from the measurement it takes. It is also likely to include a double gas-liquid exchanger which is arranged at the outlet of the evaporator (1 ') upstream of the compressor (3'), and which is composed of two exchanger elements (22 ', 23') in series.

Description

Air conditioner controlled by a device providing a measurement

  relating to the frigoriaene fluid used.

  The invention relates to air conditioners, including air conditioners demanding high reliability because of the kind of use that is made. These air conditioners are for example intended to equip cabins of air-transportable technical shelters that can be left in operation unattended for long periods. They are still likely to equip driving cabins and / or passenger rooms of public transport land vehicles and therefore to be subjected to intensive use. Such air conditioners must therefore withstand a prolonged and / or possibly intensive fault-free operation. Moreover, the maintenance operations necessary to maintain them in working order must be reduced on the one hand and, on the other hand, as far apart as possible. This leads to an attempt to improve the current air conditioners by replacing new elements that are more efficient and reliable with the constituent elements previously used. This also leads to seeking to better control the operation of these air conditioners by implementing control processes and in particular more powerful regulation. The invention therefore proposes an air conditioner including an air-cooled evaporator, an air condenser and a compressor looped together by a circuit o circulates a refrigerant. The admission of this fluid, coming from the condenser, through the evaporator is controlled by means of a pressure regulator inserted between this condenser and this evaporator and controlled from at least one device providing a measurement, relative to the fluid. circulating in the circuit.35 According to one characteristic of the invention, the air conditioner comprises at least one thermal flowmeter, positioned in a given zone of the circuit, for at least partially controlling the expander from the measurement it performs. According to another characteristic of the invention, the air conditioner comprises a thermal flux meter positioned in a given zone of the refrigerant circuit which is situated between the compressor and the condenser and which is at a zone of high pressure for the fluid in the the circuit, when the air conditioner is in operation. According to a characteristic of a variant of the invention, the air conditioner comprises a thermal flux meter positioned in the

  a given zone of the refrigerant circuit which is at the outlet of the evaporator between the latter and the compressor.

  According to another characteristic of the invention, the heat flowmeter that comprises the air conditioner, at a given zone of the refrigerant circuit, is pressed against the outer surface of a pipe portion of the circuit o circulates the refrigerant20 for this determined area of circuit. According to another characteristic of a variant of the invention, the air conditioner comprises a thermal flow meter providing a differential measurement between heat flows taken into account at two successive portions of the pipe of the evaporator which are located on either side the expected level of end of evaporation of this

  evaporator. and to which this flowmeter is thermally connected.

  According to a last characteristic of the invention, the air conditioner comprises a double gas-liquid exchanger which is disposed at the outlet of the evaporator and therefore upstream of the compressor, and which is composed of two exchanger elements placed in series and identically equipped with each a first portion and a second portion of circuits thermally associated and fluidically separated, the first two portions being arranged in series between the

  condenser and the evaporator, upstream of the latter, the two second portions being arranged in series between the condenser and the compressor. The invention, its characteristics and its advantages are specified in the description which follows in connection with the

  figures mentioned below. Figure 1 shows a diagram of an example of a known air conditioner. Figure 2 shows a diagram of an air conditioner according to the invention.

  The known air conditioner example shown in FIG. 1 comprises an air-cooled evaporator 1, an air-cooled condenser 2 and a compressor 3, which are connected in a loop by a circuit circulating a refrigerant and to which control devices are associated. and measuring equipment, as well as ancillary equipment specified below. The evaporator 1 is for example of the finned-coil type, it receives refrigerant in the liquid state coming from the condenser 2, via a dehydrating filter 4, and is associated with a fan 5 intended to force the flow of the air cooled to the volume (s) to be air conditioned. The condenser 2 is supposed to forced ventilation, it is therefore associated with a fan 6 forcing the circulation of air responsible for evacuating the calories acquired by the refrigerant during its passage through the evaporator 1 and through the compressor 3 This latter is here assumed to be of the rotary type, it compresses at high pressure the refrigerant fluid that it receives at low pressure and in gaseous form from the evaporator 1. A liquid-gas separator bottle 7 is

  placed between the evaporator and the compressor, it is responsible for retaining the droplets that may be present in the gaseous stream coming from the evaporator, so as to prevent these droplets from reaching the compressor.

  A measurement, which is conventionally temperature, is carried out via a plug 8, formed between the evaporator 1 and the separating bottle 7. This measurement is exploited by an adjustment arrangement including at least one regulator 9 which is placed between the condenser 2 and the evaporator 1 and which is responsible for ensuring a controlled expansion of the refrigerant filling the evaporator and a homogeneous filling thereof. The measurement 8 is for example made by means of a bulb 0

  arranged against the pipe connecting the evaporator outlet 1 to the outlet of the separating bottle 7.

  This bulb 0 makes it possible, as is known, to translate, in the form of fluid pressure variations, the temperature variations of the refrigerant measured at the outlet 8. The regulator 9 is, for example, of the control type

  thermostatic, it responds to the pressure variations induced by the temperature changes of the refrigerant at the bulb and is optionally controlled via a not shown electronic control circuit of the air conditioner.

  The expander 9 is connected firstly to the inlet of the evaporator to which it supplies the refrigerant in the liquid state and secondly to the outlet of this evaporator 25 via a fluid pressure equalization tube 17, the latter being then in the gaseous state.

  A charge socket 10 is generally provided on the pipe between bulb 0 and separator bottle 7 to allow refrigerant filling of the air conditioner if necessary. Pressure switches 11 and 12 are provided connected between the compressor 3 and, on the one hand, the separating bottle 7, on the other hand, the condenser 2, on the pipes respectively connecting this compressor to these two elements, so as to ensure regulating the inlet and outlet pressures of said compressor. A plug 13 for pressure gauge is provided on the pipe, connecting the compressor to

  condenser 2, which has been mentioned above.

  The expander 9 is supplied with refrigerant by the condenser 2, possibly via a filling valve 14, for example an all-or-nothing solenoid valve conventionally included in the adjustment arrangement. It is connected to the condenser 2 via the dehydrating filter 4 and an accumulator bottle 15, which constitutes a reserve of refrigerant under pressure

  and in liquid form, at the outlet of the condenser.

  At least one window liquid indicator 16 makes it possible to check the state of the circulating refrigerant at the location where this indicator is situated, here upstream of the regulator and between the dehydrating filter and the control valve. An example of an air conditioner according to the invention is shown in Figure 2, it comprises an air cooler evaporator 1 ', an air condenser 2' and a compressor 3 'similar to those provided in the air conditioner shown in FIG. fans 5 'and 6' are respectively associated one to the evaporator 1 'and the other to the condenser 2' with the same functions as those provided by the fans 5 and 6 for the evaporator 1 and the condenser 2. The evaporator 1 'receives liquid refrigerant from the condenser 2' through a circuit comprising in particular and successively a storage bottle 15 ', a filter drier 4' and a control arrangement including a regulator 9 'associated or not with a solenoid valve 14', depending on whether or not the expander is provided to control the filling of the evaporator. In the embodiment shown, a liquid indicator 16 'is also disposed downstream of the filter drier 4' relative to the condenser. The elements 4 ', 9', 15 'and 16' mentioned above respectively correspond to the elements 4, 9, 15, 16 whose functions they take over. The holder 9 'and / or the valve 14' is or may be controlled in the manner mentioned above, however preferably a control via a heat flow meter, such as in particular ', is planned; it enables the state of the refrigerant to be rapidly and finely translated at the level where the flux meter is located on the circuit inside which this fluid circulates. The flowmeter 18 'is for example a device of the type described in the document FR-A-2598803, it provides an indication in the form of an electromotive force which is intended to be taken into account by the control circuit of the air conditioner in order to control the adjustment arrangement. This measurement by flowmeter is here supposed to be carried out in a high pressure zone of the refrigerant fluid circuit of the air conditioner, therefore downstream of the compressor 3 and for example at a point of equilibrium which is substantially at the level of the condenser 2 'battery. . The flow meter 18 'is here symbolized by a cylinder surrounding the refrigerant pipe 19' connecting the compressor 3 'to the condenser 2'. In a preferred embodiment, the flux meter 18 'is in the form of a flexible printed circuit which can be wound and fixed around the pipe portion 19' chosen as the seat of the measurements. As a result, it is no longer necessary to provide a socket opening inside the refrigerant circuit for a pressure gauge, since this is already taken into account at the level of the measurement made by the flowmeter 18 . It is therefore possible to realize a completely sealed refrigerant circuit 30, as conventionally provided in domestic refrigeration appliances, taking advantage of known advantages offered in terms of maintenance and reliability by this type of circuit. In a first variant not specifically shown of the air conditioner according to the invention, it is provided to associate a flowmeter 20 'with the flowmeter 18', or possibly to substitute it, in order to carry out the same measurements, for control purposes and / or analysis and diagnosis, at another location of the air conditioner refrigerant circuit. This other location is for example provided at the outlet of the evaporator, on the pipe 21 'for transmitting the refrigerant to the compressor 3'. It then becomes possible to determine with greater precision, the physical effects on the refrigerant phenomena 10 likely to disrupt the operation of the air conditioner, including vibration and accelerations

  eventually suffered by the latter, to guard against those phenomena that are undesirable.

  According to one embodiment, the heat flux meter 20 '15 of the evaporator is preferably placed at the end of evaporation level provided for the gas-liquid interface of this evaporator.

  evaporator and is thermally connected to two successive portions of the pipe constituting the evaporator.

  These portions are for example located on either side of the location where the interface is positioned in this evaporator pipe. The flowmeter 20 'then makes a differential measurement between the heat flows respectively taken into account each at a different level of the two portions of pipe considered.25 In an alternative embodiment more specifically for air conditioners particularly likely to be subject At accelerations and vibrations during operation, such as those provided for equipping vehicles, there are provided measures specifically intended to limit the effects of these vibrations and accelerations. A first known measure is, of course, to use

  antivibration pads for fixing the air conditioner and those of its elements which are possibly capable of creating vibrations and / or being particularly sensitive to vibrations.

  As is known, the flow of refrigerant in liquid form that is supplied to the evaporator of an air conditioner is likely to be modified by external parasitic accelerations due for example to the movement of the vehicle comprising this air conditioner. There may then be either an overflow or a lack of liquid at the evaporator outlet which can lead either to a liquid blow or to overheating of the aspirated gases at the compressor, which is usually poorly supported. by the latter. Similarly vibrations and / or parasitic accelerations can cause displacements of liquid in the tubes of the evaporator and lead to the troublesome phenomena mentioned above, moreover there is a risk of malfunction of the regulator if the control signal that he receives is distorted. Another known measure to limit the effect of

  acceleration and vibration on the air conditioner consists in interposing a liquid-gas separating bottle 7 'upstream of the suction inlet of the compressor 3' to retain the refrigerant in liquid form, in particular in the event of a liquid blow.

  Another simple measure consists in providing a compressor 3 'of the volumetric type less sensitive to the shots of liquid than the piston compressors.25 Finally, according to the invention, it is planned to insert a double gas-liquid exchanger in the refrigerant circuit at the evaporator outlet in order to limit as much as possible the consequences of any liquid overflow in this evaporator. In the example shown which is shown in phantom in FIG. 2, the double exchanger consists of two gas-liquid exchanger elements 22 'and 23', for example coaxial, connected in series so as to have no effect from the point of view of the energy balance, the superheating generated there being recovered by subcooling the refrigerant in liquid form; condenser. For this purpose, the refrigerant from the condenser 2 ', via here in particular the liquid indicator 16', flows in the direction of the evaporator 1 ', in a first circuit portion of each of the exchanger elements 22' and 23 'mounted serial. The refrigerant from the evaporator 1 ', via the pipe 21', flows in a second circuit portion separate from the first circuit portion in each of the exchanger elements 22 'and 23', these second portions being connected in series, here on either side of the bulb 0 ', upstream of the separating bottle 7' and the compressor 3 '. This allows the refrigerant in liquid form possibly to reach the exchanger element 23 'in case of overflow is vaporized through this element. This simultaneously makes it possible that the essential superheating of the refrigerant at the evaporator outlet 1 'is provided by the exchanger element 22' rather than by the evaporator 1 'itself, which consequently increases the efficiency of the battery of the last. At the same time, an undercooling of the condenser liquid compensates for the overheating that has been generated elsewhere. It is then envisaged to have a flowmeter 24 'for performing differential mode measurements on either side of the exchanger element 22', for example at the level of the pipe 21 ', as in the case where a flowmeter 20 is provided. ', and at the level of the bulb 0'. The flowmeter 24 '

  then allows control of the adjusting arrangement composed of the expander 9 'and / or the solenoid valve 14'.

Claims (4)

  1 / air conditioner comprising in particular an evaporator air cooler (1 '), an air condenser (2') and a compressor (3 ') looped together by a circuit o circulates 5 a refrigerant and o the admission of this fluid, from the condenser, by the evaporator is controlled from at least one device which provides a measurement of the fluid flowing in the circuit and which acts on at least one adjustment arrangement (14 'or 9'), inserted between the condenser and the evaporator, characterized in that it comprises at least one thermal flowmeter (18 ', 20' or 24 '), positioned in a given zone of the circuit, for at least partially controlling the adjustment arrangement at 2. The air conditioner according to claim 1, characterized in that it comprises a thermal flux meter (18 ') positioned in   a given zone of the refrigerant circuit which is situated between the compressor (3 ') and the condenser (2') and which is at a high pressure zone for the fluid in the circuit, when the air conditioner is in operation .   3 / air conditioner according to claim 2, characterized in that it comprises a thermal flowmeter (20 ') positioned in   a given zone of the refrigerant circuit which is at the outlet of the evaporator (1 ') between the latter and the compressor (3').   4 / air conditioner according to claim 1, characterized in that the thermal flux meter (18 'or 20') that it comprises, at a given zone of the refrigerant fluid circuit, is pressed against the outer surface of a portion channel of the circuit o circulates the refrigerant for this area.  5 / air conditioner according to claim 1, characterized in that it comprises a thermal flux meter (20 ') providing a differential measurement between heat flows taken into account at two successive portions of the evaporator pipe which are located on the side and other than the evaporation end level of this evaporator and to which this flowmeter is thermally connected.5 6 / The air conditioner according to claim 1, characterized in that it comprises a double gas-liquid exchanger which is arranged at the outlet of the evaporator (1 ') and therefore upstream of the compressor (3'), and which is composed of two exchanger elements (22 ', 23') placed in series and identically each equipped with a first portion and a second portion of circuit thermally associated and   The two first portions are arranged in series between the condenser and the evaporator, upstream of the latter, the two second portions being arranged in series between the evaporator and the compressor.