KR20100045663A - System for controlling fluid flow and method for controlling flow alarm thereof - Google Patents

Abstract

PURPOSE: A flux control system and their flow rate method for controlling of alarm control the flow rate alarm by at the same time using the instantaneous flow rate and accumulation flow rate. The minute flux variation can be detected. CONSTITUTION: A processing unit(102) processes substrate. A supply line(108) supplies one or more drug solution. A flow meter(112) measures the instantaneous flow rate of the drug solution at the real-time. A controller(114) produces the mean value of the instantaneous flow rate. Controller produces the accumulation flow rate actually provided to the processing unit.

Description

Flow control system and its flow alarm control method {SYSTEM FOR CONTROLLING FLUID FLOW AND METHOD FOR CONTROLLING FLOW ALARM THEREOF}

The present invention relates to a flow rate control system, and more particularly, to a flow rate control system and method for controlling a flow rate alarm using an instantaneous flow rate and an integrated flow rate at the same time.

Generally, various kinds of chemical liquids are used in manufacturing processes such as semiconductors and flat panel displays. These chemical liquids are supplied to the substrate processing apparatus which processes the substrate while satisfying the process conditions such as concentration, temperature, and flow rate required during the process by the chemical liquid supply device.

For example, the sheet cleaning apparatus for cleaning a substrate includes at least one chamber for processing a process, and at least one nozzle provided in each chamber to supply a chemical liquid to the substrate. Such substrate processing apparatuses include a chemical liquid supply device that supplies chemical liquids to respective nozzles from a chemical liquid source such as a utility supplying chemical liquid in a fab itself, or a chemical central supply system (CCSS). Connected. When the chemical liquid is supplied from the chemical liquid central supply system, the chemical liquid supply device receives the chemical liquid through a pump.

In the chemical liquid supply device, a phenomenon in which the supply pressure of the chemical liquid supplied from the chemical liquid source is irregular, that is, a pressure hunting, occurs. In addition, when the chemical liquid supply device supplies the chemical liquid to at least one nozzle or simultaneously supplies the chemical liquid to the plurality of nozzles according to the process of the substrate processing apparatus, the chemical liquid is branched into the plurality of nozzles to use the nozzle when ejecting and supplying the chemical liquid. The phenomenon in which the pressure in the supply line fluctuates depending on the number, that is, the flow rate hunting is generated. These hunting phenomena cause pulsation in the flow rate when supplying the chemical liquid, and cause process defects.

Therefore, in order to stably supply the chemical liquid, a flow rate control system for controlling the alarm by monitoring the flow rate in real time is provided. For example, a flow control system monitors the flow rate of the chemical liquid in real time through a flow meter (or sensor) installed in the supply line to measure the flow rate of the chemical liquid.

1 and 2, the general chemical liquid supply device supplies and shuts off the chemical liquid to the nozzle during the process time, in order to control the flow rate. The chemical liquid supply apparatus measures the instantaneous flow rate of the chemical liquid supplied during the process time in real time, and determines the flow rate alarm using the measured instantaneous flow rate and the set alarm reference value. The alarm reference value is a set value when the process time is completed, and can be obtained as an experience value of the chemical liquid. At this time, an alarm (± Δ) between the compared instantaneous flow rate value and the set value corresponds to an alarm occurrence condition, and generates an alarm.

In this method, since the alarm reference is determined by the average value of the instantaneous flow rate, the alarm is generated by comparing the two values when the process time is completed. Therefore, even when the flow rate hunting occurs in the instantaneous flow rate at any one time point t1 or t2, it is difficult to accurately detect the flow rate hunting occurrence.

That is, when the process is in progress, the chemical liquid is supplied during the process time (S10), the instantaneous flow rate is measured in real time (S12). For example, the substrate processing apparatus is mounted on a spin chuck in which the substrate is rotatable during the process, and receives the chemical liquid to the substrate surface through the nozzle. The alarm reference value is calculated using the average value of the instantaneous flow rates measured at the end of each process, and the instantaneous flow rate and the alarm reference value are compared (S14). As a result of the comparison, if the alarm reference value exceeds the tolerance range, an alarm is generated (S16).

However, when supplying the chemical liquid, the instantaneous flow rate pulsates due to hunting phenomenon and the like and is irregularly supplied. Therefore, since the flow rate alarm is determined using the average value of the instantaneous flow rate, it is difficult to determine the minute change in the flow rate, and the hunting may cause a large error between the two values.

SUMMARY OF THE INVENTION An object of the present invention is to provide a flow control system and method for monitoring the flow rate when a chemical solution is supplied to generate an alarm.

Another object of the present invention is to provide a flow rate control system and method for controlling a flow rate alarm according to a minute flow rate change by the flow rate hunting generated during chemical liquid supply.

It is still another object of the present invention to provide a flow control system and method for controlling a flow rate alarm using an instantaneous flow rate and an integrated flow rate simultaneously.

In order to achieve the above objects, the flow control system of the present invention is characterized by controlling the flow rate alarm by using the instantaneous flow rate and the integrated flow rate at the same time. As such, the flow control system can precisely control the flow rate.

The flow control system of the present invention includes a supply line for supplying at least one chemical liquid to a processing unit for processing a substrate; A flow meter installed in the supply line to measure an instantaneous flow rate of the chemical liquid in real time; Receives the instantaneous flow rate measured from the flow meter, calculates the average value of the instantaneous flow rate during the process progress, at the same time calculates the integrated flow rate actually supplied to the processing unit, compares the instantaneous flow rate and the integrated flow rate generated when the chemical liquid supply It includes a controller for generating an alarm by determining the error.

In one embodiment, the supply line is connected with at least one nozzle for supplying a chemical to the processing unit; The integrated flow rate is a flow rate discharged from the nozzle to the processing unit.

In another embodiment, the supply line is further provided with a flow control valve for regulating the flow rate of the chemical liquid; The controller controls the opening and closing of the flow control valve.

In yet another embodiment, the controller; If the average value of the instantaneous flow rate is set as a reference value for generating an alarm, the instantaneous flow rate and the integrated flow rate are compared to calculate an error between the instantaneous flow rate and the integrated flow rate, and if the error is a condition for generating an alarm, To trigger an alarm.

Another feature of the present invention provides a flow rate alarm control method of a flow control system. This method can detect minute changes in flow rate due to the flow rate hunting during chemical liquid supply.

This method measures the instantaneous flow rate of the chemical liquid supplied in real time. The average value of the measured instantaneous flow rates is calculated. The integrated flow rate of the chemical liquid actually supplied is calculated. An alarm is generated using the instantaneous flow rate and the integrated flow rate at the same time.

In one embodiment, using the instantaneous flow rate and the integrated flow rate simultaneously; The average value of the instantaneous flow rate is set as a reference value for alarm generation.

In another embodiment, an error between the instantaneous flow rate and the integrated flow rate is calculated, and further determined whether the calculated error is a condition for generating an alarm.

In another embodiment, the integrated flow rate is a measured flow rate from the time of supplying the chemical liquid to the time of blocking the chemical liquid during the process time.

As described above, the flow rate control system of the present invention can precisely control the flow rate by determining the flow rate alarm condition in duplicate by using the instantaneous flow rate and the integrated flow rate.

In addition, the flow rate control system of the present invention can detect the minute flow rate change due to the flow rate hunting by controlling the flow rate alarm using the instantaneous flow rate and the integrated flow rate at the same time.

The embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be interpreted as being limited by the embodiments described below. This embodiment is provided to more completely explain the present invention to those skilled in the art. Therefore, the shapes and the like of the components in the drawings are exaggerated in order to emphasize a clearer explanation.

Hereinafter, embodiments of the present invention will be described in detail with reference to FIGS. 3 to 5.

3 is a view showing the configuration of a flow control system according to the present invention.

Referring to FIG. 3, the flow control system 100 supplies at least one chemical liquid to the processor 102 processing the substrate W, and monitors the flow rate according to the chemical liquid supply in real time to control the flow rate alarm. Instantaneous flow and accumulated flow are used simultaneously.

Specifically, the flow control system 100 includes a supply line 108 connected to at least one chemical supply source (or a chemical supply device) (not shown), and a supply line 108 connected to the supply line 108 to transfer the chemical solution to the processing unit 102. At least one nozzle 106 for supplying, a flow meter 112 for measuring the instantaneous flow rate of the chemical liquid supplied to the supply line 108 in real time, and a flow control valve for adjusting the flow rate of the supply line 108 ( 110) and the flow control valve 110 is controlled to supply the chemical liquid to the processing unit 102 in accordance with the process conditions, and the flow rate information (i.e., the instantaneous flow rate) measured from the flow meter 112 is measured. Receive and control a flow alarm ALARM.

The processing unit 102 receives the chemical liquid to the surface of the substrate W through the nozzle 106, and rotates the substrate W to process the substrate cleaning process. The processing unit 102 includes a support member 104 on which a substrate W is mounted. The support member 104 is provided with a spin chuck or the like to rotate the substrate (W). Therefore, the processing unit 102 sets the spin mode to auto, and the process proceeds. That is, when the process is in progress, the processing unit 102 receives the chemical liquid to the surface of the substrate W through the nozzle 106 in a state where the substrate W is seated on the support member 104 and is rotatable.

The flow meter 112 measures the flow rate of the chemical liquid supplied to the supply line 108 in real time, that is, the instantaneous flow rate and provides the flow rate information MEASURE to the controller 114.

The controller 114 controls the flow regulating valve 110 to adjust the flow rate of the chemical liquid supplied to the nozzle 106 according to the process conditions, and to measure the flow rate information MEASURE measured from the flow meter 112. The average value of the instantaneous flow rate (AVG in FIG. 4) is calculated. In addition, as shown in FIG. 4, the controller 114 calculates an integrated flow rate of the chemical liquid from the process start time to the process completion time, that is, from the chemical liquid supply to the shutoff section. The accumulated flow rate is actually the flow rate discharged from the nozzle 106 to the processing unit 102. In addition, the controller 114 compares the instantaneous flow rate MEASURE measured from the flow meter 112 with the accumulated flow rate actually discharged from the chemical liquid, and generates a flow rate alarm using an error according to the comparison result.

Therefore, the flow rate control system 100 of the present invention calculates and compares the instantaneous flow rate actually flowing in the supply line 108 with the integrated flow rate supplied during the process time, and determines an alarm reference. That is, the error caused by the comparison of the two values is minimized, and through this, the flow rate hunting is more accurately determined and the alarm is managed.

4 is a waveform diagram illustrating a state in which the chemical liquid supply is controlled using the instantaneous flow rate and the integrated flow rate of the flow control system shown in FIG. 3.

Referring to FIG. 4, when the process proceeds, the chemical liquid is supplied and blocked during the process time. At this time, the flow rate control system 100 compares the integrated flow rate based on the instantaneous flow rate MEASURE. This is because the error range of the average value of the instantaneous flow rate AVG and the integrated flow rate uses only the average value of the existing instantaneous flow rate shown in FIG.

For example, if the mean value of the instantaneous flow rate is 100 cc / min and the error is ± 5 cc / min, the conventional method determines the alarm criterion by the mean value, so if the average value is greater than 105 cc / min or less than 95 cc / min. It will generate an alarm. Even when the flow rate hunting occurs at the time points t1 and t2, it is difficult to detect the flow rate hunting occurrence because the alarm is determined using only the average value of the instantaneous flow rate.

However, in the present invention, under the same conditions, the mean value AVG of the instantaneous flow rate and the instantaneous flow rate and the integrated flow rate are simultaneously compared at the time t1 (or t2), and the mean value of the instantaneous flow rate is 100 cc / min, and the integrated flow rate is 97. If cc / min, the instantaneous flow rate at time t1 (or t2) due to flow hunting is 95 cc / min (or 102 cc / min), the error between the instantaneous flow rate and the integrated flow rate is ± 3 cc / min, Figure 1 The margin of error is less than the margin of error. Therefore, the flow control system can precisely control the alarm by using the reduced error compared to the existing one.

5 is a flowchart illustrating a procedure for controlling the chemical liquid supply and the flow rate alarm using the instantaneous flow rate and the integrated flow rate according to the present invention. This procedure is a program processed by the controller 114, which is stored in a memory (not shown) of the controller 114.

Referring to FIG. 5, when the process proceeds in step S150 and the chemical liquid is supplied, an average value of the instantaneous flow rate and the instantaneous flow rate is calculated in step S152. At this time, the instantaneous flow rate is measured in real time using a flow meter. The average value of the instantaneous flow rate is set as an alarm reference value for alarm generation. Therefore, the controller 114 receives the instantaneous flow rate MEASURE measured from the flowmeter 112 and calculates an average value AVG of the instantaneous flow rate.

In step S154, the accumulated flow rate actually supplied, that is, discharged from the nozzle 106 is calculated. The integrated flow rate is the flow rate from the time of supplying the chemical liquid to the time of blocking the chemical liquid during the process time.

In step S156, the instantaneous flow rate and the integrated flow rate are compared to determine whether an error occurs. As a result of the determination, if an error occurs by comparing the instantaneous flow rate and the integrated flow rate, the flow advances to step S158 to determine whether the error has reached the alarm reference value. In other words, if the error is outside the range for alarm generation, the procedure proceeds to step S160 to generate an alarm to the outside.

In the above, the configuration and operation of the flow control system according to the present invention has been shown in accordance with the detailed description and drawings, which are merely described by way of example, and various changes and modifications may be made without departing from the spirit of the present invention. It is possible.

1 is a waveform diagram showing a state of controlling a chemical liquid supply using an average flow rate according to an embodiment of the prior art;

FIG. 2 is a flowchart showing a procedure for controlling chemical liquid supply using the average flow rate of the embodiment shown in FIG. 1; FIG.

3 shows a configuration of a flow control system according to the present invention;

4 is a waveform diagram showing a state of controlling the chemical liquid supply using the instantaneous flow rate and the integrated flow rate of the flow rate control system shown in FIG. 3; And

5 is a flowchart illustrating a procedure for controlling the chemical liquid supply and the flow rate alarm using the instantaneous flow rate and the integrated flow rate according to the present invention.

Explanation of symbols on the main parts of the drawings

100: flow control system 102: processing unit

104: support member 106: nozzle

108: supply line 110: flow control valve

112: flow meter 114: controller

Claims (8)

In the flow control system: A supply line for supplying at least one chemical liquid to a processing unit for processing a substrate; A flow meter installed in the supply line to measure an instantaneous flow rate of the chemical liquid in real time; Receives the instantaneous flow rate measured from the flow meter, calculates the average value of the instantaneous flow rate during the process progress, at the same time calculates the integrated flow rate actually supplied to the processing unit, compares the instantaneous flow rate and the integrated flow rate generated when the chemical liquid supply Flow control system comprising a controller for generating an alarm by determining the error. The method of claim 1, The supply line is connected to at least one nozzle for supplying a chemical liquid to the processing unit; And the integrated flow rate is a flow rate discharged from the nozzle to the processing unit. The method according to claim 1 or 2, The supply line is further provided with a flow control valve for controlling the flow rate of the chemical liquid; And the controller controls opening and closing of the flow regulating valve. The method according to claim 1 or 2, The controller; If the average value of the instantaneous flow rate is set as a reference value for generating an alarm, the instantaneous flow rate and the integrated flow rate are compared to calculate an error between the instantaneous flow rate and the integrated flow rate, and if the error is a condition for generating an alarm, Flow control system, characterized in that to generate an alarm. In the flow alarm control method: Measuring the instantaneous flow rate of the supplied chemical liquid in real time, calculating the average value of the measured instantaneous flow rate, calculating the integrated flow rate of the actually supplied chemical liquid, and generating an alarm using the instantaneous flow rate and the integrated flow rate simultaneously. A flow rate alarm control method. The method of claim 5, Simultaneously using the instantaneous flow rate and the integrated flow rate; The flow rate alarm control method, characterized in that for setting the average value of the instantaneous flow rate as a reference value for the alarm generation. The method of claim 6, Simultaneously using the instantaneous flow rate and the integrated flow rate; Calculating an error between the instantaneous flow rate and the integrated flow rate, and further determining whether the calculated error is a condition for generating an alarm. The method according to any one of claims 5 to 7, The cumulative flow rate is a flow rate alarm control method, characterized in that the measured flow rate from the time of supplying the chemical liquid during the process time to the time of blocking the chemical liquid.

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