CA1216045A - Monitoring and control for evaporator - Google Patents

Abstract

PATENT OF INVENTION METHOD AND DEVICE FOR MONITORING AND CONTROLLING AN EVAPORATOR Invention by: Christian BOUSSICAULT SOCIETE ANONYME DITE: SOCIETE NATIONALE ELF AQUITAINE Method and device for monitoring and controlling an evaporator, in particular the evaporator a heat pump according to which the difference between the upstream and downstream temperatures of the air current passing through the evaporator is compared to a predetermined difference at predetermined times. Application to heat pumps. Figure 1. Société Anonyme known as: Société Nationale ELF Aquitaine

Description

lZlG ~ 5 The present invention relates to a method and a dis-positive of ~ eillance and control of an evaporator in view to detect the presence of frost on its surface and trigger its elimination. It concerns in particular the case where the evaporator is that of a heat pump.
The principle of a heat pump is well known from those skilled in the art and it is simply recalled that the pumps heat using air as a cold source include an evaporator where this air exchanges its calories with a refrigerant circulating inside this evaporator which therefore vaporizes. When using of such a heat pump for heating, the air used as cold source is air taken outside the room to heat. Under certain conditions, the use of this outside air can cause frost to form on the evaporator which curbs the heat exchange between the two fluids penalizes the performance of the installation and requires a defrosting operation. This operation which requires stopping the pump should only be performed if you want to optimize the installation. We therefore provides in these installations per-putting to detect the presence of frost and trigger the o defrosting. These devices are usually consisting of sensors to measure the loss of load undergone by the air during its passage on the evaporator or measure the evaporation temperature by measurement directly on the wall of the evaporator. We can also use timer systems that initiate defrost at predetermined time intervals. However, these 3 ~ embodiments have the drawback that all measurements taken are absolute measurements which do not take into account the initial conditions of the tallation and its operating conditions, nL either external conditions and their variations. From external conditions influencing the appearance of frost, we can cite the hygrometric degree of air, its temperature.

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Among the installation conditions, it is necessary to monitor the air flow which, if it is ~ fixed for a installation r and can be considered constant, varies from one installation to another. All of these conditions then attempt to set up the installation on site.
On the contrary, the inventio ~ provides a device and a method for detecting the presence of frost which put to overcome these drawbacks whose functioning does not depend on the variations of the different above parameters and which do not require any setting linked to the site where the evaporator is installed.
For this, the invention provides a method of monitoring and control of an evaporator in which a first fluid circulates, said evaporator being at the same time tact of a second fluid set in motion so as to overturn it, the second fluid being liable to yield its calories at first ~ luide and cause its evapo-ration, said method allowing the detection of the pre-sence of sour on the evaporator and the elimination of this one, characterized in that it consists in measuring a parameter Pl, representative of the state of the second fluid upstream of the evaporator and a representative P2 parameter the state of the same second fluid downstream of the evaporator, these measurements being carried out at instants ti, determined from an initial time, to calculate for each instant the difference ~ Pi existing between the two para-meters Pl and P2, to compare at each instant ti the difference ~ Pi with the difference ~ Po measured at the initial instant, this comparison being made in the form of a subtrac-tion whose result is a parameter ~ and to control the defrosting of the evaporator when ~ is greater than a set value Cl.
This process therefore makes it possible not to control the defrosting qula ~ one escient and therefore yue the reference setpoint is provided by the first measurement, it makes it possible to overcome external conditions.

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According to a preferred characteristic of the method according to the invention, the di: Eference ~ Po is compared at least once, at time to, has a value of consi-gne Co, and the degi ~ rage is controlled when ~ Po is greater than less than Co. This Co value is chosen according to the characteristics of the device. This step of the method makes it possible to ensure that the first measure taken as a reference, was not ~ aite in the presence of frost. or any other harmful parameter, and preferably it is repeated several times if necessary and the installation is stopped if, after a number of trials, for example four, the difference at Po did not become greater than the setpoint Co.
Finally, according to another preferred characteristic of the method according to the invention, the control of the defrosting of the evaporator is interrupted when parameter P2 becomes greater than a setpoint C2.
Preferably, the measured parameter is the temperature or pressure.
The invention also provides a monitoring device.
lance and control of an evaporator associated with a circuit circulation of a first refrigerant and put in contact with a second fluid set in motion by a fan lator so ~ cross the evaporator, characterized by what it includes at least a pair of temperature sensors crossed out on both sides of the evaporator and contact with said second fluid, treatment means signals from these sensors, said means per-constantly making the difference between temperatures measured by both detectors and the compare to the initial gap existing when setting operation of the installation so as to generate a signal control actuating a device for dega ~ rage of the evapo-according to the result of said comparison.
According to a preferred embodiment, the sensors of te ~ perature generate a continuous signal representative of , ~
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the temperature and the means of treatment are killed by a microprocessor.
Finally, according to a preferential characteristic of the invention, the temperature sensors are constituted by resistances varying with temperature, streets by a roughly adjustable intensity current and mounted in series with two standard resistors, the monitoring and control device further comprising: 7 ~ 23L ~
- a signal multiplexing means provided with at least four entry ways of which at least two re ~ olvent each one analog signal representative of the terminal voltage variable resistances, including two among the others each receive a signal representative of the voltage across the stallion resistors ~, this means of plexing also comprising ~ an exit channel and means selection to select at any time one of said input channels in order to communicate it cation with said exit route, - a means of transformation allowing to transform signals from the means of multiple ~ age into signals al-of which one of the constitutive parameters is proportional tional to the voltage of the corresponding signal, said signals being directly processed by the microprocessor.
According to the invention, the transformation means can generate alternative signals whose period is pro-portional to the corresponding signal voltage but it can, according to another embodiment, generate signals whose frequency is proportional to the voltage of the corresponding signal.
According to a preferred characteristic, the means are made up of a microprocessor per-~ being to make a comparison ~ sound per second.
The invention will be better understood on reading the re following description of an embodiment, given as nonlimiting example, description ~ alte with reference to annexed drawings on which:
- The f ~ gure 1 shows a first embodiment of the invention - Figure 2 shows a second embodiment of the inventlon.
Figure 1 shows schematically the part evaporation of a heat pump with which we have associated a device for detecting frost according to the invention.
The evaporator (1 ~ in which the fluid circulates is placed in an air stream (2) produced by a ventilator (3). The fluid circulation circuit (4) refrigerator comprises an expansion valve (35).
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,; ~, It is closed by the rest of the exchange installation of heat pump calories represented by the rectangle ~ 5) and which includes, in particular and in a usual manner a compressor and a condenser. The circuit (4) includes a bypass loop (6) allowing bypass cl ~ condenser and regulator (35). This loop is controlled by a three-way valve (7) associated with a servomotor (30). The fan (3 ~ is fitted with an interrup-electromagnetic ~ tor (8). Two temperature sensors ~ 9) and (10) are placed in the stream of a; r (2), the probe (9 upstream of the evaporator and the probe (10) downstream.
of these probes is connected to a microprocessor (11), by the intermediary ~ re cables ~ 12) and (13) and conver-analog digital weavers (31 ~ and (32).
The device thus represented operates from the next way. The system is put into normal operation.
bad, that is to say that the refrigerant circulates in the evaporator, the bypass circuit (6) is closed, the fan (3) feeds and draws in the air flow (2) to and through the evaporator (1 ~, and the evaporator is not not frosted. After a certain time tl, it is considered that the steady state is reached.
From this time tl, the microprocessor of surveillance starts and performs, at moments ~ i separated by regular time intervals of the order of 1 second, the calculation of the difference ~ T between the temperature strike measured by probe 9 and that measured by probe 10. The first measurement made ~ To is taken as a measurement of reference and therefore put in memory. At every instant ti, the microprocessor compareA Ti to ~ To. As soon as ~ Ti becomes su-perieur à ~ To increased by a constant K, the microprocessor develops a signal actuating the switch (8) of the ventila-tor. This signal also acts on the servomotor (30 ~ which operates the three-way valve (7) so that the refrigerant circulates in the bypass circuit ment ~ 6). Simultaneously, the microprocessor monitors the : temperature measured by the downstream probe (10) and as soon as it this again becomes greater than a limit value, the micropro-stopper works out ur. new signal which by action of the switch (8) and the servomotor (30) puts the system back in ~ normal operation so that the cycle resumes as previously.
This system also monitors installation at startup which allows taking into account the situation where the evaporator would be ~ drunk during the measurement of ~ To, or that linked to faulty operation of the refrigerant circulation circuit. For this the microprocessor compares the interval ~ To to a value ~ limit and triggers defrosting if ~ To is greater than this value. In fact, and in this case we consider that the exchange did not do well and the evaporator is frosted. This operation can be repeated a number of times until normal operation is obtained but the microprocessor will trigger a total stop if this function normally not obtained after a certain number defrosting: for example 4. This phase of the process allows therefore ensure that the value ~ To, taken into account during all monitoring, corresponding to a normal state of device.
Figure 2 shows a variant of the invention that temperatures are measured using a device comprising two probes mounted in parallel with two standard resistors, a multiplexer and a generator of digital signals ~ The microprocessor assumes the calculation temperatures and defrost monitoring.
In this Figure 2, the identical elements ~ those in Figure 1 have the same markings. From either side of the evaporator are placed temperature probes (1013 and (102) each constituted by a variable resistance depending on the temperature. These two probes are mounted in series with two standard resistors ~ placed ~ in the housing (103) ~ ui also allows the supply of the probe assembly -standard resistances by continuous voltage. The cables (105) and (106) are conductors to other son allowing the serialization of probes and resistors and allowing _ 7 - ~ 2 ~
also the measurement of the voltage across the resistors variables. A multiconductor cable (107) connects the bolt (103) has a multiplexer (109). This cable provides power the input bus of the multiplexer has ~ ec voltages limits of variable resistances and across resistances standard tances. The output of the multiplexer is connected to a amplifier (110) then to an analog converter digital (eu) which is connected to the microprocessor 1112), itself connected to the multiplexer (109) by a cable (120) transport of orders.
The mic ~ oprocessor performs the addressing of the multiplexer and the rules of three allowing the calculation temperatures, and also does the various operations necessary to detect the presence of frost on the evaporator.
The analog converter (111) is, preferably rence, a VCO which delivers a frequency at its output proportional to the voltage present at the input.
You can also use a width modulator of pulses so the microprocessor will work at from a period, by counting pulses whose number is directly proportional to the period.
The device represented may have different monitoring bodies allowing for example to verify ~ ue the fan is operating or that its access by outside air is not hampered by such elements like dead leaves for example.
This device is particularly well suited to monitoring the evaporator of a heat pump such than that described in the published French patent application under n ~ 2,478,792 ~ Heating installation for premises for residential or industrial use ~.
Finally, in ~ ention is not limited to the modes of realisatio ~ described, on the contrary it encompasses all ~ arianteS.
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Claims (10)

The embodiments of the invention, concerning the-what an exclusive property right or lien is claimed, are defined as follows: 1. Method for monitoring and controlling a evaporator in which a first fluid circulates, said fluid evaporator being in contact with a second fluid put in movement so as to cross it, the second fluid being likely to give up calories to the first fluid and cause its evaporation, said process allowing the detection of the presence of frost on the evaporator and elimination thereof, characterized in that it consists to measure a parameter Pl, representative of the state of the second fluid upstream of the evaporator and a parameter P2 representing sensitive to the state of the same second fluid downstream of the evacuation porator, these measurements being carried out at times ti, determined from an initial instant, to be calculated for every moment the difference .DELTA. Pi existing between the two parameters Pl and P2, to be compared at each instant ti the difference .DELTA. Pi with the difference .DELTA. Po measured at the moment initial, this comparison being made in the form of a subtraction whose result is a .delta parameter. and to order der the defrost of the evaporator when .delta. is greater than a setpoint Cl. 2. Method according to claim 1, characterized in that the difference .DELTA. Po is compared at least once, at time to, at a setpoint Co and the degi-vrage is ordered when .DELTA. Po is greater than Co. 3. Method according to claim 1, characterized in that the defrost control is interrupted when the parameter P2 becomes greater than a setpoint value C2. 4. Method according to claim 1, 2 or 3, characterized in that the parameter measured is the pressure. 5. Method according to claim 1, 2 or 3, characterized in that the measured parameter is the temperature ture. 6. Monitoring and control device of an evaporator associated with a circulation circuit of a first refrigerant and brought into contact with a second fluid set in motion by a fan so as to pour the evaporator, characterized in that it comprises minus a pair of temperature sensors located on the and other side of the evaporator and in contact with said second fluid, means for processing signals from these sensors, said means allowing at all times to establish the difference between the temperatures measured by the two detectors and compare it to the initial deviation existing when the installation of the so as to generate a control signal actuating a device defrosting of the evaporator depending on the result of said comparison. 7. Device according to claim 6, charac-terrified in that the temperature sensors generate a continuous signal representative of the temperature and that said processing means are constituted by a micro-processor. 8. Device according to claim 7, charac-terized in that the temperature sensors are made up by resistances varying with temperature, streets by a roughly adjustable intensity current and connected in series with two standard resistors, said device positive further comprising - a signal multiplexing means provided with at least four entry lanes, at least two of which each receive a analog signal representative of the terminal voltage variable resistances, including two among the others each receive a signal representative of the voltage across the standard resistors, this means of plexing also comprising an exit route and means selection to select at any time one of said input channels in order to communicate it cation with said exit route, - a means of transformation allowing to transform signals from the multiplexing means into signals alternatives of which one of the constituent parameters is pro-portable to the corresponding signal voltage, said signals that can be directly processed by the micro-processor. 9. Device according to claim 8, character-laughed at in that the means of transformation generates alternative signals whose period is proportional to the voltage of the corresponding signal. 10. Device according to claim 8, charac-in that the means of transformation generates alternating signals whose frequency is proportional to the voltage of the corresponding signal.