FR2674945A1 - DEVICE FOR REGULATING THE CONTINUOUS OPERATION OF A CONVICTIVE DRYER INTENDED FOR DRYING PRODUCTS IN BAND, IN PARTICULAR THE TEXTILE TYPE. - Google Patents

Abstract

The present invention relates to a device for regulating the continuous operation of a convective dryer intended for drying strip products, in particular of the textile type. This device is characterized in that it comprises a central processing unit (13) collecting all the information communicated through various measuring means (9, 11) and, more particularly, the energy consumption by the heating means ( 7) and the speed of travel of the strip (3) in the dryer (2) and which, starting from setpoint data, such as the temperature of the hot air blown into this dryer (2), ensure, through appropriate control means (14) and by means of extraction means (8), the adjustment of the extraction flow rate of the air charged with water vapor from the dryer (2) in order to guarantee an optimum of operation of the latter taking into account its energy consumption and its maintenance cost.

Description

The invention relates to a device for regulating the operation of

  continuous of a convective dryer intended for the drying of band products in particular of the textile type, comprising: belt drive means provided with variable speed motor means, temperature-controlled heating means for the production of hot air for drying; means for extracting an adjustable flow rate of the air charged with water vapor from the dryer means for measuring the energy consumption by the heating means, means for measuring the residual moisture of the strip at the outlet of the dryer; means for measuring the speed of travel of this band and means for controlling this speed of movement of the

  band as a function of the measured residual humidity.

  The present invention will find its application in the context of convective dryers which, by continuous operation, ensure the drying of a strip product. Thus, this invention will relate, more

  particularly, textile materials in the form of tape.

  In fact, in this field, two parameters must be taken into consideration mainly because of their influence on speed.

drying.

  Thus, this drying speed is proportional to the difference in temperature between, on the one hand, the air blown into the dryer and arriving at the level of the strip and, on the other hand, the temperature of this

tape itself.

  Moreover, the lower the degree of hygrometry inside the dryer, the greater the temperature difference mentioned above and, therefore, the greater the

  drying speed will be important.

  However, it is observed that if one also takes into account at the level of these data, of the energy consumption of the dryer, one finds that it

  represents a counteracting factor to that of the drying rate.

  Indeed, if we take into account the fact that the consumption of a dryer are distributed around the following values o% for the losses by the walls, O o for the losses by the fumes (hot air evacuated with the vapors); O for the evaporation of the water it follows that the higher the water vapor concentration of the air extracted from the dryer is greater, that is to say the higher the degree of hygrometry is

  important, the energy consumed by the dryer is low.

  There exists therefore, an optimum of operation which can not be determined theoretically, so much the calculation involves parameters sometimes difficult

  to predict or measure and fluctuate over time.

  Thus and in the context of tissues, these parameters are, in particular, the nature of the fibers but also their origin, the mode of spinning, the texture of the fabric, the surface mass of this fabric, the dimensions of the

width, permeability to air.

  Of course, to these parameters, related to the strip product, properly so called, are added many others which are dependent on the dryer technology Thus, it would be appropriate, for the determination of this optimum operation of the dryer, to hold account, also, and this as

  for example, clogging filters.

  Returning now, to the operation of the kilns known at present, it is necessary, initially, to recall the structure Thus, these dryers, outside the enclosure that constitutes them, include means to ensure the drive and the scrolling of the strip product inside this enclosure, these drive means being provided with

motor means with variable speed.

  Furthermore, these dryers comprise, on the one hand, temperature-controlled heating means for the production of hot air intended to be blown into the enclosure of the dryer in order to ensure the drying and on the other hand, extraction means, with an adjustable flow rate, to guarantee the evacuation, at this chamber, of the steam-laden air

of water.

  Such known driers are also provided with a number of means for measuring the operating conditions.

  means for measuring energy consumption by the heating means.

  For example, it may be an electric meter in the case of an electric heating system or a flow meter when the energy

  consumed is a fluid, such as gas or fuel.

  Furthermore, there are means for measuring the residual moisture at the strip product at the outlet of the dryer, as well as means of

  measuring the speed of scroll of this product in band.

  Thus, after displaying, as setpoint data, a residual moisture content, servo means are able to adjust the speed of travel of the band to reach precisely, this rate

  humidity at this strip at the outlet of the dryer.

  Until now, the management of the operating conditions of this dryer was under the control of an operator who, to perform this function, used, on the one hand, data that were communicated to him by the various measuring means and, on the other hand, from his experience in the field. However, this manual management method makes it possible to achieve very rarely the optimal operation of the dryer, especially if one also wants to take into account, for the determination of this optimum, maintenance costs and, more particularly, labor costs which, well

  heard, are related to the duration of use of the equipment.

  This cost of maintenance and driving is of little importance when the company is in a position of under-capacity of production. In these conditions, the labor costs are constant and it is impossible to

can minimize them.

  On the other hand, in the event of overcapacity of production, only the measurement of the product in strip which it is necessary to dry is imposed and it is in these conditions that it is advisable to take into account as well the energy consumption as the maintenance costs and driving knowing that the longer the dried tape length per unit of time is important, the more energy is consumed, but the lower the maintenance and driving costs

will be high.

  However, it is precisely in these conditions that the operator is not in

  able to guarantee the operation of the dryer according to an optimum.

  Also, the present invention proposes to remedy this drawback.

  For this purpose, the invention relates to a device for regulating the continuous operation of a convective dryer intended for the drying of textile products, in particular of the textile type, comprising: belt drive means provided with variable speed motor means ; temperature-controlled heating means for producing hot air for drying; means for extracting an adjustable flow rate of the air charged with water vapor from the dryer; means for measuring the energy consumption by the heating means; means for measuring the residual humidity of the strip at the outlet of the dryer; means for measuring the speed of travel of this band and means for controlling the speed of travel of the band according to the measured residual humidity, characterized in that it comprises a central processing unit collecting all the information communicated through the different measuring means and, more particularly, the energy consumption by the heating means and the running speed of the strip and which, starting from setpoint data, such as the temperature of the hot air blown into the dryer, ensure, through appropriate control means and through the extraction means, the adjustment of the extraction rate of the air charged with water vapor dryer 2 to ensure a optimum operation of the latter taking into account: the energy consumption of the dryer 2 expressed by the function: F 2 bx Q / V ob is the cost of the fuel unit Q l fuel consumption per unit of time V is the production speed in metric per unit of time and the maintenance and driving cost expressed by the function Fl a I V o

  a is the cost of maintenance and driving per unit of time.

  The advantages obtained thanks to this invention consist, of course, in that it makes it possible to ensure, automatically, the

  optimum operation of a convective dryer of strip products.

  Other objects and advantages of the present invention will be apparent from

  course of the following description relating to an embodiment

  which is given only as an indicative and non-limiting example.

  The understanding of this description will be facilitated by referring to

  attached drawing showing in FIG. 1 the diagram of a dryer of products in strips incorporating a device for the regulation of sound

  operation, according to the invention.

  The present invention as represented in this FIG. 1 relates to a device 1 for regulating the operation of a convective dryer 2 intended for the continuous drying of strip products 3

especially of textile type.

  Thus, this dryer 2, outside the enclosure 4 which composes it, comprises means 5 for driving the band 3 through the dryer 2, these drive means 5 comprising motor means to

variable speed 6.

  Furthermore, this dryer 2 is provided with temperature-controlled heating means 7 ensuring the production of hot air intended to be blown

  in the chamber 4 in order to guarantee the drying of the strip product 3.

  In addition, extraction means 8 surmount the enclosure 4 of the dryer 2 in order to ensure the evacuation of the air charged with water vapor according to a

flow that can be adjusted.

  Said dryer 2 is further provided with a number of measuring means through which it is possible to determine its level of

  function or the quality of the drying produced.

  Thus, it comprises means 9 for measuring the energy consumption by the heating means 7 For example, such measuring means 9 may be constituted either by a flow meter when the fuel used is gas or fuel oil, by a simple electricity meter when the energy used to heat the air for drying is

electrical energy.

  This dryer 2 further comprises means 10 for measuring the residual moisture of the strip product 3 at the outlet of the enclosure 4. Thus, to such measuring means 10 may be associated control means capable of controlling the speed of travel of the strip 3 so that, at the outlet of the dryer 2, its humidity level corresponds to a

displayed setpoint.

  Finally, note that this running speed of the strip product 3 is itself detected through appropriate measuring means 11. Of course, it will be possible to find in the middle of this dryer 2 many other detectors or measuring means which may be decisive for its operation. Thus, means for measuring the temperature 12 placed inside the enclosure 4 of the dryer 2 will, through a continuous control, to ensure a perfect regulation of the temperature of the hot air blown into the chamber 4 through the means of

heating 7.

  In fact, the present invention aims to ensure optimized operation of this type of convective dryer 2, this with regard to a certain

  number of parameters but also imposed operating data.

  Thus, the regulating device 1, according to the present invention, comprises a central processing unit 13 collecting the information at the output of the measuring means and, more particularly, measuring means 9 of the energy consumption by the heating means 7 as well as measuring means 11 of the running speed of the strip 3 and which, starting from setpoint data such as the temperature of the hot air blown into the dryer, ensure, through appropriate control means 14 and by means of intermediate extraction means 8, the setting of the extraction rate of the dryer 2 of the air charged with water vapor to ensure an optimum operation of the dryer 2, this depending on the parameters that constitutes the energy consumption of the latter and its

  cost of maintenance and driving.

  In fact, the energy consumption is expressed by the following function F 2 = bx QIV ob is the cost of the fuel unit Q the fuel consumption per unit of time V the production speed in metric per unit of time Quant the cost of maintenance and driving, it is expressed by the function: Fl = a / V o U a: is the cost of maintenance and driving per unit of time In this regard, it should be noted that this cost of maintenance and driving per unit of time can integrate labor costs but

  also all costs that are related to the operation of the dryer 2.

  Consequently, the function of which the central processing unit 13 proposes to determine the minimum through the management of the operation of the dryer 2 is as follows:

F = F 1 + F 2

  In fact, in order to achieve this goal, this central processing unit 13 performs a calculation by recurrence. More precisely, through the information communicated to it by means of the measuring means 9, 11, the unit of central processing 13 determines the value of F or CO. Then, this central processing unit 13, by means of said control means 14 intervenes on the extraction means 8 in order to increase or decrease the evacuation flow DO. air charged with water vapor of an increment I whose module is also a datum of

setpoint (D1 = DO + I).

  Then it comes to evaluate the new value of F is Cl which corresponds, as it were, to the new operating cost of the dryer 2 This cost CI is then evaluated with respect to the previous cost CO through a test

  to subtract at cost CO the cost Cl.

  In the case where the test C = CO CI is greater than zero, the central processing unit 13 stores the lowest cost (CO = Cl) in memory and then makes a new change of the flow rate by means of the said control means 14 this according to the same increment and in the same direction of change as before Thus if, during the previous cycle the flow Dl had been increased by an increment I this new flow Dl, when the test is greater than zero, is again increased by same increment I. On the other hand, if the test C = CO Cl is less than zero, which corresponds to an operating cost of the dryer 2 greater than the previously evaluated cost before change of the flow rate, the central processing unit 13 proceeds with a new change in this rate, taking into account the last value D1 conferred on the latter and modifying it this time by two increments 2 x I but in the opposite direction to the direction of

  change chosen during the previous flow modification.

  For example, if, in order to determine the operating cost of the dryer 2, the processing unit 13 had just increased the flow Dl of extraction of the air charged with water vapor and that the C = GO test C1 has proved negative, this central processing unit 13 will reduce this rate D1 of a module corresponding to twice the increment 2 × I. Finally, if the test determines a value lying in a close interval from zero, the central processing unit detects the optimum operating point of the dryer 2 and maintains the adjustment of the extraction rate of the air charged with water vapor, for a period that can be prolonged before restarting the cycle. As for the control means 14 on which the central processing unit 13 intervenes, these are, of course, adapted to the means

extraction 8.

  Thus, in the case where the latter are in the form of at least one motorized flap, said control means 14 will be constituted, advantageously, by a stepper motor actuated through a

  impulse control from the central processing unit 13.

  In the case of extraction means 8 in the form of at least one fan, such control means 14 consist substantially of a variable speed drive which converts a voltage signal from the processing unit. central 13, either a new voltage signal when the motor of this fan is DC type or frequency in the context of asynchronous technology. The main advantages obtained thanks to this invention consist, essentially, in that it is no longer the responsibility of the operator to determine the optimum operation of the dryer 2 which leads to a more efficient management.

  of this dryer 2 and, consequently, to better results.

  Although the invention has been described with respect to a particular embodiment, it is understood that it is in no way limited and that various modifications of shapes, materials and combinations thereof can be made. various elements, without departing from the framework and

the spirit of the invention.

Claims (3)

claims   1 Device for regulating the continuous operation of a convective dryer (2) intended for drying web products (3), in particular of the textile type, comprising: drive means (5) for the belt (3) provided with means variable speed motors (6); temperature-controlled heating means (7) for the production of hot air for drying, means for extracting (8) an adjustable flow rate of the steam-laden air from the dryer (2); means (9) for measuring the energy consumption by the heating means (7); means (10) for measuring the residual humidity of the strip (3) at the outlet of the dryer (2); means (11) for measuring the running speed of this band (3); and means making it possible to control this running speed of the band (3) as a function of the measured residual humidity; characterized in that it comprises a central processing unit (13) collecting all the information communicated through the various measuring means (9, 11) and, more particularly, the energy consumption by the heating means (7). ) and the running speed of the belt (3), which, starting from setpoint data such as temperature, hot air blown into the dryer (2), ensure, through appropriate control means (14); ) and by means of the extraction means (8), the adjustment of the extraction rate of the air charged with water vapor from the dryer (2) in order to guarantee an optimum operation of the latter taking into account of: the energy consumption of this dryer (2) expressed by the function: F 2 = bx QIV ob: is the cost of the fuel unit Q: the fuel consumption per unit of time V: is the speed of production in footage per unit of time and the cost of my intention and conduct expressed by the function Fl = a / V o   a is the cost of maintenance and driving per unit of time.   2 control device according to claim 1 characterized in that the extraction means (8) are constituted by at least one motorized flap and the control means (14) are in the form of a stepper motor actuated through an impulse command in   from the central processing unit (13).   3 Control device according to claim 1, characterized in that the extraction means (8> are in the form of at least one fan and the control means (14) are constituted by a variable speed drive which converts a voltage signal from the central processing unit (13) to a new signal, either in voltage, either in frequency.