BE1011932A3 - Method and device for cool drying - Google Patents

Abstract

Method for cool drying gas that contains water vapour, whereby the gas is led through a secondary section of a heat exchanger (1) of which the primary section is the evaporator (2) from a cooling circuit (3) that also contains a compressor (5). The said compressor is driven by an electric motor (4), a condenser (6), and an expansion means (7) between the outlet of the condenser (6) and the entrance of the evaporator (2), and whereby the evaporator temperature or pressure is measured and the said cooling circuit (3) is controlled as a function of the measured evaporator temperature or pressure. Specific features are that the revolutions of the motor (4) are controlled as a function of the measured evaporator temperature or pressure in such a way that the load on the cooling capacity is altered without the formation of ice in the evaporator.<IMAGE>

Description

       

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  Method and device for cooling drying.



  This invention relates to a method of cooling drying gas containing water vapor, in particular air, wherein this gas is passed through the secondary part of a heat exchanger, the primary part of which is the evaporator of a cooling circuit which also contains a compressor, which is driven by an electric motor, a condenser, an expansion means between the condenser outlet and the evaporator inlet, the evaporator temperature or pressure being measured and the said refrigeration circuit being controlled in function of the evaporator temperature or pressure measured.



  Such methods are used, inter alia, to dry compressed air.



  Compressed air delivered by a compressor is in most cases saturated with water vapor or, in other words, it has a relative humidity of 100%. This means that condensation occurs at the slightest temperature drop. The condensation will cause corrosion in pipes and tools and the devices will show premature wear.



  Hence, the compressed air is dried, which can be done by cooling in the aforementioned manner. Air other than compressed air or other gases can also be dried in this way.



  Refrigeration drying is based on the principle that

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 lowering the temperature condenses moisture from the air or gas, after which the condensation water in the liquid separator is separated and after which the air or gas is reheated so that this air or gas is no longer saturated. The heat in the evaporator is dissipated by the refrigeration circuit.



  The same applies to gas other than air and whenever reference is made to air hereinafter, the same also applies to gas other than air.



  In practice, there is an ISO standard that determines what the dew point and the corresponding lowest air temperature can be at reference conditions.



  In order to prevent the lowest air temperature from falling below 0 ° C and thus freezing the evaporator, it is a necessary condition that the evaporator temperature is higher than 0 ° C.



  For this purpose, the temperature is measured at the inlet of the evaporator or, since there is a fixed relationship between the evaporator temperature and the evaporator pressure for a particular refrigerant in the refrigerant circuit, the pressure is measured before or after the evaporator.



  The cooling circuit is then controlled in such a way that the evaporator temperature or evaporator pressure has the desired value and, for example, the evaporator pressure corresponds to a temperature that is a few degrees below the required lowest air temperature or LAT, but is nevertheless not below 0 ° C.

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 In known methods of refrigeration drying, the constant-frequency motor of the refrigeration circuit compressor is turned on and off in function of the evaporator temperature. If this evaporator pressure drops too low, this motor is stopped.



  If the evaporator pressure then becomes too high because the expansion valve is still open, the engine will be restarted.



  Such control allows if the load falls below the cooling capacity, the compressor is turned off, reducing energy consumption.



  The surplus of cooling capacity is stored in a thermal mass. However, this control is very disadvantageous since the compressor is switched on and off continuously at a small load, while the evaporator pressure and dew points also fluctuate greatly. In addition, the refrigeration dryer must be constructed quite large.



  Another possibility to control the evaporator pressure would be to select the evaporator large enough and return hot gases at the compressor outlet to the compressor inlet by means of a bypass.



  This control method has the disadvantage that, since the compressor motor is in continuous operation, even with no or low load, the energy consumption is equal to the energy consumption at nominal load, since the high and low pressures in the refrigeration circuit are continuously kept constant.

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 The object of the invention is a method of refrigeration drying which does not have the aforementioned and other disadvantages and with which energy savings can be obtained in a simple manner, without pressure fluctuations in the cooling circuit and without great wear of the compressor and its motor.



  This object is achieved according to the invention in that the speed of the motor is controlled in function of the measured evaporator temperature or pressure such that the cooling capacity is adapted to the load, but without ice forming in the evaporator.



  Instead of turning the engine on or off, its speed is adjusted. By increasing the speed of the engine, more mass flow of coolant can be pumped around and thus more cooling power can be supplied.



  Preferably, the speed of the motor is controlled by changing the frequency of the supply current.



  In a special embodiment of the invention, the ambient temperature is measured and the speed of the motor is regulated taking into account the measured ambient temperature.



  At high ambient temperatures, where the air or gas is also relatively warm and may contain more moisture than when it is cold, cooling it to 3 ° C in the heat exchanger is not necessary to obtain dry air. The aforementioned refrigeration dryers thus show too much

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 high energy consumption and require relatively large and expensive components to provide cooling power. By taking this ambient temperature into account, the required cooling capacity can be kept lower in such a way that the cooling dryer can be manufactured less large.



  Preferably, the speed of the motor of the compressor is controlled such that the lowest air or gas temperature at the outlet of the evaporator is 200C lower than the measured ambient temperature without, however, falling below 3C.



  It is assumed that when the outgoing air or the outgoing gas has a relative humidity of 50%, there is no longer a risk of corrosion in pipes and equipment and the aforementioned control device ensures that this relative humidity does not exceed 50%.



  The invention also relates to an apparatus for refrigeration drying or a refrigeration dryer which is particularly suitable for applying the above-described method.



  The invention relates in particular to a device for refrigeration drying, which has a heat exchanger, the primary part of which is the evaporator of a cooling circuit which also contains a compressor driven by an electric motor, a condenser, an expansion medium between the output of the condenser and the evaporator inlet, a control device for controlling said motor and associated measuring means for measuring the evaporator temperature

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 or pressure, while the secondary part of the heat exchanger forms part of a pipe for the gas to be dried and a liquid separator is arranged in this pipe at the outlet of this heat exchanger,

   the device comprising means for controlling the speed of the motor, while the control device controls these means in function of the evaporator temperature or pressure measured by the measuring means.



  Preferably, the means for controlling the speed of the motor consist of a frequency converter.



  In a special embodiment of the invention, the refrigeration dryer comprises means for measuring the ambient temperature which are also coupled to the control device and this control device is such that it controls the speed of the motor both in function of the evaporator temperature or pressure measured by the measuring means and in function of the temperature measured by the means for measuring the ambient temperature.



  With the insight to better demonstrate the features of the invention, a preferred embodiment of a refrigeration dryer according to the invention is described below, by way of example without any limiting character, with reference to the accompanying drawing, in which a block diagram of a refrigeration drying device according to the invention is shown. displayed.



  The refrigeration drying device shown schematically in the figure mainly comprises a heat exchanger 1, the primary part of which forms the evaporator 2 of a

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 cooling circuit 3 in which a compressor 5 driven by an electric motor 4, a condenser 6 and an expansion valve 7 are successively arranged.



  This cooling circuit is filled with cooling fluid, for example freon 404a, the flow sense of which is indicated by arrow 8.



  The secondary part of the heat exchanger 1 forms part of the conduit 9 for moist air to be dried, the flow direction of which is indicated by the arrow 10.



  After the heat exchanger 1 and thus at its outlet, a liquid separator 11 is arranged in the line 9.



  Optionally, before it reaches the heat exchanger 1, this conduit 9 may extend in part through a pre-cooler or recuperation heat exchanger 12 and then, after the liquid separator 11, extend through the recuperation heat exchanger 12 again, in countercurrent with said portion.



  The heat exchanger 1 is a liquid-air heat exchanger and can constructively form a whole with the optional recovery heat exchanger 12, which is an air-air heat exchanger.



  The expansion valve 7 is a thermostatic valve, the thermostatic element of which is coupled by a copper conductor 13 to a bulb or "bulb" 14 which is arranged at the outlet of the evaporator 2 on the cooling circuit 3 and is filled with the same cooling medium.

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  However, in a variant not shown in the figure, this expansion valve is an electronic valve which is coupled to a temperature meter which is arranged on the end of the evaporator 2 or after it.



  With small refrigeration dryers, the expansion valve 7 can be replaced by a capillary.



  The compressor 5 is a volumetric compressor which at the same speed delivers practically the same volume flow rate, for example a spiral compressor, while the motor 4 is an electric motor whose speed is adjustable by changing the frequency.



  This motor 4 is therefore coupled to a frequency converter 15 which is controlled by a control device formed by a built-in PID controller 16.



  For example, the frequency converter 15 can control the frequency between 0 and 400 Hz and forms means for controlling the speed of the motor 4.



  In a first embodiment, the PID controller 16 is connected via a line 17 to measuring means 18 to measure the evaporator pressure, for example a pressure transmitter with a pressure range of -1 to 12 bar which converts the pressure into an electrical signal, in particular a current which is arranged at the inlet or the outlet of the evaporator 2, as shown in dashed line in the figure.



  In a second embodiment, the PID controller 16 is via

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 a conduit 19 connected to measuring means 20 for measuring the evaporator temperature, for example a thermocouple in the cooling circuit 3, at the inlet of the evaporator 2 and thus between this evaporator 2 and the expansion valve 7.



  After all, for a given cooling fluid there is a fixed relationship between the evaporator temperature and the evaporator pressure. The higher the temperature, the higher the pressure. Strictly speaking, this relationship is not linear, but in the scope, which is between OOC and 25 C, the deviation from a linear is negligible in practice.



  In both embodiments, the PID controller 16 is connected via a line 21 to means 22 for measuring the ambient temperature and converting this temperature into an electrical signal, in particular a current.



  The operation of the refrigeration dryer is as follows: The air to be dried is passed through the pipe 9 and thus through the heat exchanger 1, in countercurrent with the refrigerant fluid in the evaporator 2 of the refrigeration circuit 3.



  The moist air is cooled in this heat exchanger 1, so that condensation is formed which is separated in the liquid separator 11.



  The cold air, which after this liquid separator 11 contains less moisture but still has a relative humidity of 100%, is placed in the recovery heat exchanger 12

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 heated, causing the relative humidity to drop to about 50%, while the fresh air to be dried in this heat exchanger 12 is already partially cooled before being added to the heat exchanger 1.



  The air at the outlet of the heat exchanger 12 is therefore drier than at the inlet of the heat exchanger 1.



  To avoid freezing evaporator 2, the air in heat exchanger 1 is not cooled below 3 C, this is the LAT at low ambient temperatures.



  At higher ambient temperature, the LAT may be higher and it is cooled to a LAT that is 200C lower than the ambient temperature, and therefore in any case not lower than 3 C.



  If the LAT is too high, it will not be cooled sufficiently and therefore not enough moisture will be condensed for the air to dry sufficiently.



  This LAT is 2 to 30C above the actual evaporator temperature measured by the measuring means 20.



  The aforementioned conditions of LAT are met by controlling the speed of the motor 4 with the aid of the PID controller 16 and the frequency converter 15 controlled by it, in function of the evaporator temperature measured by the measuring means 20, in one embodiment, or the measuring means 18 measured evaporator pressure, in the other embodiment.

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 The cooling capacity is equal to the mass flow of cooling fluid circulating in the cooling circuit 3 multiplied by the enthalpy difference of the air before and after the heat exchanger 1. By increasing the speed of the motor 4, the compressor 5 can pump more mass flow and thus at the same enthalpy difference more power to be delivered.

   The mass flow rate is the volume flow rate of the compressor 5 multiplied by the density of the cooling fluid in the suction state, which itself depends on the evaporator temperature and superheat.



  The PID controller 16 adjusts the measured temperature or pressure by adjusting the speed so that this temperature is a few degrees lower than the aforementioned LAT, yet higher than OOC, respectively the evaporator pressure is reached corresponding to a temperature a few degrees below the LAT and is, for example, equal to 1 C, where for freon R404a the evaporator pressure is then approximately 5.2 bar effective.



  In this way, the cooling capacity is adapted to the load.



  Since the ambient temperature is also measured by means 22, the associated PID controller 16 can take this temperature into account.



  With the aid of the PID controller 16 and the frequency converter 15 controlled by it, the speed of the motor 4 is then regulated in such a way that, as long as the ambient temperature is low, and in particular lower than 23 C, the aforementioned condition is met and thus the LAT the exit from

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 the evaporator 2 is about 3 C, but at a higher ambient temperature this LAT 20 C is lower than the temperature measured by the
 EMI12.1
 r means 21 measured ambient temperature.



  The evaporator pressure has a set point a few degrees lower than the desired LAT. The temperature obtained by subtracting about 22 ° C from the ambient temperature can be set as the set point of the PID controller 16.



  Optionally, a minimum and a maximum set point can be set in the PID controller 16, the minimum being 1 C. When setting the PID controller 16, this set point can be adjusted, for example, via a control panel or via an analog input.



  For example, the frequency is controlled between 30 and 75 Hz.



  The maximum load on the refrigeration dryer is relatively small, since at higher ambient temperatures the LAT may be higher than 3 ° C, which reduces the cooling capacity and thus allows the components to be cheaper and cooling fluid to be saved.



  In the condenser 6, the gaseous cooling fluid heated by the compression in the compressor 5 is cooled to a liquid form, and a fan or cooling water can be used to dissipate the heat to the environment.



  If the pressure in condenser 6 is too high, the motor 4 switches off automatically.

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  After the condenser 6, the liquid cooling fluid can optionally be collected in a vessel and / or further cooled by an additional heat exchanger.



  The expansion valve 7 expands the liquid cooling fluid to a constant evaporator pressure, which naturally entails a drop in temperature. The expansion valve 7 only controls the superheat in evaporator 2 and ensures that evaporator 2 is always used optimally, but cannot be used to control the evaporator pressure or temperature.



  By using a thermostatic expansion valve 7, there is always an overheating after the evaporator 2, as a result of which there is no danger of cooling liquid in the compressor 5 and a liquid separator in the cooling circuit 3 is unnecessary and the amount of cooling fluid is limited.



  This superheat is measured by subtracting the temperature measured by the bulb 14 from the evaporator temperature measured either before the evaporator 2 (internal equalization) or after the evaporator (external equalization). This difference is compared by the expansion valve 7 with a set value and, in case of deviation, the expansion valve 7 will correct this by opening or closing.



  The degree of superheat has an influence on the LAT, but it can be assumed that the superheat valve 7 keeps this superheat almost constant.

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 If necessary, this influence of overheating can be taken into account by, for example, a kind of master-slave control circuit. The slave control circuit is the previously described control with the PID controller 16, while the master control circuit could adjust the set point of the evaporator pressure or temperature in function of the actual LAT and thus, for example, reduce the set point if the LAT remains too high because the superheat after the evaporator 2 is too high.



  Although the evaporator pressure or temperature is controlled by changing the speed, in case the load is zero, the possibility can still be provided to switch off the motor 4 completely, for example by placing a thermostat sensor in the heat exchanger 1 which, if the temperature in evaporator 2 nevertheless becomes zero degrees, switch off the motor 4 and restart it when the temperature has risen to 3 ° C.



  The invention is in no way limited to the embodiments described above and shown in the appended drawing, but such a method and device for cooling drying can be realized in different variants without departing from the scope of the invention.



  In particular, instead of a PID controller 16, the controller may contain another controller, for example a PI or P controller. Although it is preferable to also take the ambient temperature into account, among other things, in order to limit the power of the device, in a simpler embodiment the control can

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 of the speed of the motor 4 only in function of the evaporator temperature or pressure.



  Instead of moist air, in the same way and with the same device, other gas containing water vapor than air can be dried. The LAT is then the lowest gas temperature.


    

Claims (1)

Conclusions.   1.- Method for cooling drying gas containing water vapor, this gas being passed through the secondary part of a heat exchanger (1), the primary part of which is the evaporator (2) of a cooling circuit (3) which is also a compressor (5 ) driven by an electric motor (4), a condenser (6), an expansion means (7) between the condenser outlet (6) and the evaporator inlet (2), and wherein the evaporator temperature or pressure is measured and the said cooling circuit (3) is controlled in function of the measured evaporator temperature or pressure, characterized in that the speed of the motor (4) is controlled in function of the measured evaporator temperature or pressure in such a way that the cooling capacity is adapted to the load but without icing in the evaporator (2). Method according to claim 1, characterized in that the speed of the motor (4) is controlled by changing the frequency of the supply current.   Method according to claim 1 or 2, characterized in that the speed of the motor (4) is regulated so that the evaporator temperature is 2 to 3 C below the lowest gas temperature (LAT) or the evaporator pressure is kept at a value corresponding to with a temperature that is 2 to 3 C below this lowest gas temperature (LAT), whereby this lowest gas temperature (LAT) is kept at a minimum of 3 C.  <Desc / Clms Page number 17>  Method according to one of the preceding claims,  EMI17.1  characterized in that the ambient temperature is measured and the speed of the motor (4) is regulated taking into account the measured ambient temperature.   Method according to claim 4, characterized in that the speed of the motor (4) of the compressor (5) is regulated such that the lowest gas temperature (LAT) at the outlet of the evaporator (2) is 20 C lower than the measured ambient temperature without, however, falling below 3 ° C. Method according to one of the preceding claims, characterized in that before the evaporator (2) the cooling medium is expanded by an expansion valve (7) and the superheat after the evaporator (2) is measured and compared with a set value, wherein, in case of deviation, the expansion valve (7) corrects this by opening or closing. Method according to any one of the preceding claims, characterized in that the gas to be dried is heated after the heat exchanger (1) and the liquid separator (11) in a recovery heat exchanger (12) by the gas to be dried which is fed to the first heat exchanger (1). ) is supplied.  EMI17.2   8. Device for refrigeration drying, which has a heat exchanger (1), the primary part of which is the evaporator (2) of a cooling circuit (3), which also contains a compressor (5) driven by an electric motor (4), a condenser (6), a  <Desc / Clms Page number 18>  expansion means (7) between the output of the condenser (6) and the input of the evaporator (2), a control device (16) for controlling said motor (4) and associated measuring means (18 or 20) to measure the evaporator temperature or measure the pressure, while the secondary part of the heat exchanger (1) forms part of a pipe (9) for the gas to be dried and a liquid separator (11) is arranged in this pipe (9) at the outlet of this heat exchanger (1) characterized in that the device has means (15)  for controlling the speed of the motor (4) while the control device (16) controls these means (15) in function of the evaporator temperature or pressure measured by the measuring means (18 or 20). Device according to claim 8, characterized in that the means for controlling the speed of the motor consist of a frequency converter (15). Device according to claim 8 or 9, characterized in that it comprises means (22) for measuring the ambient temperature which are also coupled to the control device (16) and this control device (16) is such that it controls the speed of the motor ( 4) controls both in function of the evaporator temperature or pressure measured by the measuring means (20 or 18) and in function of the temperature measured by the means (22) for measuring the ambient temperature. Device according to any one of claims 8 to 10, characterized in that the control device is a PID controller (16), a PI controller or a P controller.