A Method Of Controlling The Temperature Of A Silicon Melt In A Furnace


Updated about 2 years ago

Abstract

This invention relates to a method for controlling the temperature in a silicon melt furnace to improve the dendritic silicon web production having a pair of dendrites at opposing web edges. An image of each dendrite emerging from a silicon melt is generated. Thickness of each dendrite is calculated and the temperature of the furnace adjusted to maintain the thickness in a predetermined range.

Information

Application ID IN/PCT/2001/1090/CHE
Invention Field AGROCHEMICALS
Date of Application 2001-08-01
Publication Number 28/2005

Applicants

Name Address Country Nationality

Specification

The invention relates to a method of controlling the temperature of a silicon melt in a furnace. Dentritic web silicon substrates are produced for solar cell manufacturing by growing thin ribbons of single crystal material from liquid silicon. The ribbon produced typically appears as a thin (100 microns) single crystal structure approximately 5 cm wide, bounded at each vertical edge by a single silicon dendrite with a thickness of approximately 700 microns. In the growth process, the center section is actually a liquid surface tension film supported by the two dendrites which have begun to solidify beneath the surface of the undercooled melt. As the crystal is pulled from the melt surface, the liquid film freezes in a stable, smooth, single crystal state.
Control of temperature and temperature distribution is absolutely critical in this process, requiring stability on the order of 0.1°C at an absolute temperature of 141°C. The thickness of the edge dendrites are extremely sensitive to temperature, and provide a convenient method of controlling temperature at the crystal based on the size of these dendrites. If the melt temperature is too low, the web degenerates from a single crystal state; if the melt temperature is too high, the crystal pulls away from the melt due to insufficient dendrite growth beneath the melt. Each of these conditions is sufficient reason to terminate the growth of an individual crystal. The throughput of the process and hence the prospect for achieving a low cost process is extremely dependent on average crystal length.
The existing art involves controlling the melt temperature through the use of a pyrometer based temperature controller which controls a single point in the hot zone. An operator adjusts the setpoint of the loop by observing the dendrite thickness of the growing crystal. In addition, the operator adjusts the lateral temperature symmetry of the melt by moving an induction coil relative to the hot zone. The operator makes the adjustments based on the visually perceived difference in the thickness of each of the two edge dendrites. The operator must continually look through a quartz window at a dendrite which is located approximately 50 cm away and make a visual estimate of dendrite edges which are only 0.7 mm thick. The range of thickness control necessary to maintain continuous growth is about +/-.2 mm. This manual control method is extremely subjective, being based on the operator's vision, and requires a substantial investment of the operator's time, continually observing the crystal.

The invention comprises a method and system for automatically iens;ng and measuring the dendrites, and controlling the dendrite thickness, hereby keeping temperature under control during the dendritic web manufacturing )rocess. The average melt temperature is controlled by automatic adjustment of smperature based on the average dendrite thickness. Temperature symm.etn/ is ichieved by feedback of dendrite thickness differences to a stepper motor which noves the induction coil relative to the hot zone.
4
An image of each dendrite emerging from a silicon melt in a dendritic ilicon web growth furnace is generated and supplied to a thickness calculation init. The images are preferably multiplexed so that alternate images of the iendrite pair are supplied to the thickness calculation unit. The thickness of each iendrite is calculated by digitizing each dendrite image, detecting the dendrite idges for each dendrite image, and calculating the thickness from the dendrite dge information. Preferably, a plurality of dendrite thickness calculations is veraged.
The results of the calculation step can be used in a open loop mode y displaying the results to an operator for use in manually adjusting the overall jrnace temperature and the lateral furnace temperature distribution. The results an also be used in a closed loop mode by generating a thickness feedback signal, nd supplying the thickness feedback signal to a first control loop for monitoring verall furnace temperature; and by generating a thickness difference signal spresentative of the difference in thickness between the pair of dendrites and :sing the thickness differential signal to control a lateral furnace temperature iistribution adjustment mechanism.
When operated in the closed loop mode, the invention provides a ontrol system that automatically controls melt temperatures in a web crystal" irowth furnace by using the edges of the crystal as a sensor. This control system rovides a significant reduction in labor for the crystal growth process, and icreases furnace throughput through the reduction of crystal termination events; lereby increasing average crystal length. When the control system is operated in le open loop mode, the invention provides information to the operator which enables more precise manual feedback to control the crystal edge thickness.

Accordingly, the present invention provides a method of controlling the temperature of a silicon melt in a furnace used to produce a dendritic silicon web having a pair of dendrites at opposing web edges, said method comprising the steps of:
(a) generating an image of each dendrite emerging from a silicon melt in a dendritic silicon web growth furnace;
(b) calculating the thickness of each dendrite; and
(c) using the calculated thickness to adjust the furnace temperature to maintain the dendrite thickness within a predetermined range.
For a fuller understanding of the nature and advantages of the invention,
reference should be had to the ensuing detailed description taken in ^.

conjunction with the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a schematic block diagram showing the main functional components of the dendrite control system; and
FIG. 2 is a schematic block diagram showing control logic for the system of Fig, 1.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
With reference to Fig. 1, the dendrite thickness control system includes two CCTV cameras 12, 14 which are mounted on the exterior of a conventional furnace shell 18 in a fixed alignment. Each camera is aimed at a different one of the two edge dendrites of web 10, receiving the image through a reflection from a beam splitter mirror 20 which allows simultaneous observation of the dendrites by an operator who looks through the mirror. The cameras 12, 14 are fitted with an optical lens system 22 which provides a magnification of about 10 X when focused at an image distance typical of the location of the dendrites as they emerge from the melt contained in the furnace. The camera images are multiplexed via a multiplexer unit 24, and coupled to an image digitization unit 26, In the preferred embodiment, the images from the left and right cameras are digitized and Stored in unit 26 on an alternating basis. Each image appears solid black against a white background of the silicon melt. The dendrite images are displayed by a conventional real time video image display unit 28.
In the preferred embodiment, the software accesses three lines of pixel data across the dendrite image and executes a standard 3X3 edge detection convolution on the image in order to detect the outer edges of the magnified dendrite. With a pixel array of 512 by 512, a single pixel represents about 25 microns of dendrite thickness. The pixel separation of the two edges is calculated, averaged in block 34 over five consecutive measurements to smooth the resulting data, and converted to a physical measurement of edge thickness of each dendrite in microns. A fixed calibration in pixels per micron is provided in the software for this last conversion by means of a block 36 of predetermined threshold and scaling information. A calibration is generated for each camera on each furnace by running the measurement system in the open loop mode and comparing resultant data with actual micrometer measurements (signified by hardware edge measurement block 38) of dendrites on a grown web.

This system can be used in both an open loop mode and a closed loop mode. In the open loop mode, the system provides continuous data to the operator by means of display unit 28, so that the operator can make appropriate manual adjustments to overall temperature and lateral temperature distribution based on.the dendrite thickness information provided by the Fig. 1 system. In the closed loop mode, the measurements from the two dendrites are used in two ways.
As illustrated in Figure 2, in the closed loop mode the average thickness of both left and right dendrites is first determined in functional blocks 42, 44 and sent to a digital proportional-integral-derivative (PID) control block 46 in real time. The PID block 46 outputs a signal which modifies the set point of the base loop temperature in block 50. The modified setpoint from block 50 is supplied to a switch 51 having a manual mode position and an automatic mode position. When operating in the closed loop mode, switch 51 is in the auto position in which the base loop temperature setpoint change from block 50 is coupled to a base temperature control loop 60 Control loop 60 includes a single color pyrometer 62 which provides a feedback signal representative of average system temperature to a digital PID algorithm block 63. Operator selectable tuning parameters are furnished from a reference block 64 as system parameter inputs to block 63. Block 63 is used to control an induction coil/susceptor heating unit via an induction heating inverter 66. In general, base control loop 60 uses the calculated base loop temperature setpoint and the actual measured overall furnace temperature (as measured by pyrometer 62) to control the average furnace temperature. This cascaded control loop allows continuous control of average system temperature based on the thickness of the dendrites.
A second PID loop comprising blocks 70, 72, 74 and 76 functions by accepting the difference in thickness between the two dendrites as an input, and generating an output signal which controls the lateral position of the induction coil in the furnace. The coil is driven by a stepper motor which accepts direction and number of steps information directly from this block 76. By adjusting the lateral location of the coil in this way, the temperature distribution across the crystal from dendrite to dendrite is controlled. As suggested by block 72, this loop always has a setpoint of zero deviation between the dendrites in order to maintain symmetry of the growing crystal.
This invention has been prototyped and demonstrated to work effectively, with a measurement resolution of up to 10 microns, and control of dendrites to within +/- 50 microns. Early results on over 50 crystals have demonstrated a 40% increase in average crystal length over a process in v^hich the

invention was not used.
The invention enables longer average silicon ribbon lengths to be obtained by eliminating a common source of crystal terminations: viz. inadequately controlled temperature and temperature distributions. The longer the average silicon ribbon length, the closer the process approaches the optimum goal of continuous ribbon growth. Continuous silicon growth provides substantial throughput increases and decreases nonproductive furnace time. Also, the operator involvement is decreased with this invention, essentially lowering the labor cost per crystal and substantially reducing subjective errors in the hbbon manufacturing process.
While the above provides a full and complete disclosure of the preferred embodiments of the invention, various modifications, alternate constructions and equivalents will occur to those skilled in the art. Therefore, the above should not be constnjed as limiting the invention, which is defined by the appended claims,

WE CLAIM:
1. A method of controlling the temperature of a silicon melt in a furnace used to
produce a dendritic silicon web having a pair of dendrites at opposing web
edges, said method comprising the steps of:
(a) generating an image of each dendrite emerging from a silicon melt in a dendritic silicon web growth furnace;
(b) calculating the thickness of each dendrite; and
(c) using the calculated thickness to adjust the furnace temperature to maintain the dendrite thickness within a predetermined range.

2. The method as claimed in claim 1, wherein said step (a) of generating includes the steps of producing an image of each dendrite and multiplexing the dendrite images to provide alternate images of the dendrite pair.
3. The method as claimed in claim 1, wherein said step (b) of calculating includes the steps of digitizing each dendrite image, detecting the dendrite edges in each dendrite image, and calculating the thickness from the dendrite edge information.
4. The method as claimed in claim 1, wherein said step (b) of calculating includes the step of averaging a plurality of dendrite thickness calculations.
5. The method as claimed in claim 1, wherein said step (c) of using includes the step of displaying the results of said step (b) of calculating to an operator for use in manually adjusting the furnace temperature.

6. The method as claimed in claim 1, wherein said step (c) of using includes the
step of supplying a thickness feedback signal to a control loop for maintaining
furnace temperature.
7. The method as claimed in claim 1, wherein said step (c) of using includes the
step of generating an average thickness feedback signal from the difference
between successive dendrite pair thicknesses, and supplying the average
thickness feedback signal to a control loop for maintaining flimace
temperature.
8. The method as claimed in claim 7, further including the step as providing a
dendrite thickness set point and comparing the dendrite thickness set point with
the average thickness feedback signal.
9. The method as claimed in claim 1, wherein said step (c) of using includes the
step of generating a thickness differential signal representative of the difference
in thickness between the pair of dendrites, and using the thickness differential
signal to control a lateral furnace temperature distribution adjustment
mechanism.
10. The method as claimed in claim 9, further including the step of providing a
thickness difference set point signal, and comparing the thickness difference set
point signal with the thickness differential signal.

Documents

Name Date
in-pct-2001-1090-che abstract.pdf 2011-09-05
in-pct-2001-1090-che claims-duplciate.pdf 2011-09-05
in-pct-2001-1090-che claims.pdf 2011-09-05
in-pct-2001-1090-che correspondence-others.pdf 2011-09-05
in-pct-2001-1090-che correspondence-po.pdf 2011-09-05
in-pct-2001-1090-che description(complete)-duplciate.pdf 2011-09-05
in-pct-2001-1090-che description(complete).pdf 2011-09-05
in-pct-2001-1090-che drawings-duplciate.pdf 2011-09-05
in-pct-2001-1090-che drawings.pdf 2011-09-05
in-pct-2001-1090-che form-1.pdf 2011-09-05
in-pct-2001-1090-che form-19.pdf 2011-09-05
in-pct-2001-1090-che form-26.pdf 2011-09-05
in-pct-2001-1090-che form-3.pdf 2011-09-05
in-pct-2001-1090-che form-5.pdf 2011-09-05
in-pct-2001-1090-che form-6.pdf 2011-09-05
in-pct-2001-1090-che others.pdf 2011-09-05
in-pct-2001-1090-che petition.pdf 2011-09-05
Abstract_Granted 200789_06-06-2006.pdf 2006-06-06
Claims_Granted 200789_06-06-2006.pdf 2006-06-06
Description_Granted 200789_06-06-2006.pdf 2006-06-06
Drawings_Granted 200789_06-06-2006.pdf 2006-06-06

Orders

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