A mono-crystalline silicon growth apparatus includes a furnace, a support base, a crucible, a heating module disposed outside of the crucible, and a heat adjusting module above the crucible. The heat adjusting module includes a diversion tube, a plurality of heat preservation sheets, and a hard shaft. The diversion tube includes a tube body and a carrying body connected to the tube body. The heat preservation sheets are sleeved around the tube body and are stacked and disposed on the carrying body. The hard shaft passes through the tube body and does not rotate. The hard shaft includes a water flow channel disposed therein and a clamping portion configured to clamp a seed crystal. Therefore, a fluid injected into the water flow channel takes away the heat near the clamping portion. A heat adjusting module and a hard shaft of the mono-crystalline silicon growth apparatus are provided.

A lift assembly includes a lift housing, a drum with a helical groove about its exterior surface, and a drive shaft coupled to the drum to cause the drum to rotate. A roller guide mounted to the lift housing engages the helical groove of the drum such that rotation of the drum causes the drum to translate due to the engagement of the helical groove of the drum with the roller guide. The roller guide can be part of a roller guide assembly that includes a mounting plate and a shaft.

An ingot puller apparatus for producing a doped single crystal silicon ingot includes a housing defining a chamber, a crucible disposed within the chamber, and a dopant injector extending into the housing. The dopant injector includes a delivery module attached to and extending through the housing into the chamber. The delivery module includes a dopant injection tube positioned within the chamber and a vaporization cup positioned within the dopant injection tube and the chamber. The second valve selectively channels the liquid dopant into the vaporization cup and the vaporization cup vaporizes the liquid dopant into a vaporized dopant.

A lift assembly includes a lift housing, a drum with a helical groove about its exterior surface, and a drive shaft coupled to the drum to cause the drum to rotate. A roller guide mounted to the lift housing engages the helical groove of the drum such that rotation of the drum causes the drum to translate due to the engagement of the helical groove of the drum with the roller guide. The roller guide can be part of a roller guide assembly that includes a mounting plate and a shaft.

A roller guide assembly for use in lifting a seed coupled to a cable includes a mounting plate, a shaft, and a roller guide. The mounting plate has a throughhole. The shaft is coupled to the mounting plate such that the shaft is movable relative to the mounting plate in a direction that is generally perpendicular to a central axis of the shaft. The roller guide is rotationally coupled about the shaft and generally positioned within the throughhole of the mounting plate such that at least a portion of the roller guide extends out of the throughhole.

A mono-crystalline silicon growth apparatus includes a furnace, a support base, a crucible, a heating module disposed outside of the crucible, and a heat adjusting module above the crucible. The heat adjusting module includes a diversion tube, a plurality of heat preservation sheets, and a hard shaft. The diversion tube includes a tube body and a carrying body connected to the tube body. The heat preservation sheets are sleeved around the tube body and are stacked and disposed on the carrying body. The hard shaft passes through the tube body and does not rotate. The hard shaft includes a water flow channel disposed therein and a clamping portion configured to clamp a seed crystal. Therefore, a fluid injected into the water flow channel takes away the heat near the clamping portion. A heat adjusting module and a hard shaft of the mono-crystalline silicon growth apparatus are provided.

Ingot puller apparatus for preparing a single crystal silicon ingot by the Czochralski method are disclosed. The ingot puller apparatus includes a heat shield. The heat shield has a leg segment that includes a void (i.e., an open space without insulation) disposed in the leg segment. The heat shield may also include insulation partially within the heat shield.

The present invention relates to a method of growing a silicon ingot comprising a dopant material having a segregation coefficient of k, wherein the concentration of the dopant is axially substantially uniform throughout the ingot. The method comprises the steps of providing a crucible having an inner growth zone in fluid communication with an outer feed zone, and the inner growth zone and the outer feed zone have cross-sectional areas that are can be used to determine conditions for maintaining dopant uniformity for the specific dopant material used. A crystalline growth system for growing at least one uniformly doped silicon ingot is also disclosed.

An ingot puller for producing a doped single crystal silicon ingot includes a housing defining a chamber, a crucible disposed within the chamber, and a dopant injector attached to and extending into the housing. The chamber is maintained at a first pressure. The dopant injector includes a reservoir for containing a liquid dopant, a feed tube positioned within the chamber and connected to the reservoir, and a vaporization cup positioned within the feed tube and the chamber.

Crystal pulling systems having a fluid-cooled exhaust tube are disclosed. The fluid-cooled exhaust tube extends through the reactor housing and into the reaction chamber. In some embodiments, the exhaust tube extends through the bottom of the crystal puller housing and through a bottom heat shield within the ingot puller housing.