CN201198501Y - Gradient temperature field heating element - Google Patents
Gradient temperature field heating element Download PDFInfo
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- CN201198501Y CN201198501Y CNU2008201168584U CN200820116858U CN201198501Y CN 201198501 Y CN201198501 Y CN 201198501Y CN U2008201168584 U CNU2008201168584 U CN U2008201168584U CN 200820116858 U CN200820116858 U CN 200820116858U CN 201198501 Y CN201198501 Y CN 201198501Y
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Abstract
The utility model relates to a gradient-type temperature-field heating element, in particular relates to a heating element that is applied to the crystal growth furnace and can effectively establish appropriate temperature gradient field, and belongs to the technical field of the crystallization craftwork, which is mainly characterized in that a plurality of heating plates with longitudinal cross section and transverse section are reasonably combined to form one or more circuit loops; different heats can be produced at different resistance parts, so that a given temperature gradient can be produced in the growth area; the distribution of the temperature field can be flexibly adjusted by adjusting the cross section shapes and the height of the heating plates. When in use in a crystal growth furnace, only one temperature control device is required, thereby not only simplifying the operation and reducing the cost, but also favoring the stabilization of the temperature field. The heating element is particularly applicable to the crystal growth furnace of descent method, temperature gradient method, resistance heating pulling method, Bridgman method and heat exchanging method, and also is applicable to other heat treatment devices requiring the temperature gradient distribution.
Description
Technical field
The utility model relates to a kind of gradient type temperature field heating element, is specifically related to a kind of heating element that is applied to can effectively set up in the crystal growing furnace suitable temperature gradient field, belongs to the crystallization processes technical field.
Background technology
Very important condition of growing high-quality crystalline is exactly that a suitable temperature field will be arranged.The distribution of the temperature in the growing system in other words in the crystal, in the melt and the thermograde on the solid-liquid interface crystalline quality is had decisive influence.Yet different crystal has different characteristics, needs the major defect of control also often different, and they require nature also inequality for warm field condition.Therefore, so-called suitable temperature field does not have the criterion of a strictness.In general, need big thermograde (particularly near interface), and plain crystal or easy rimose crystal adopt less thermograde for doped crystal; In addition, when generally adopting the interface of flat (or dimpling) to come growing crystal, then help the inhomogeneity improvement of crystal.But, under given conditions, adopt protruding interface growth crystal that its favourable one side is also arranged.In a word, the growing system of an optimization requires the temperature field to have controllability more flexibly, to satisfy the growth needs of different crystal.
The distribution in temperature field is mainly by the structure of thermal insulation layer, the crucible position in heating element and factors such as the flow decision of heat-eliminating medium in the crystal growing process.The flow that wherein changes the position of crucible and heat-eliminating medium is limited to the regulating effect of temperature, though and the setting that changes thermal insulation layer can reach comparatively ideal regulating effect, its performance period is longer, and need expend suitable manpower and materials.It should be noted that the required heat of crystal growth is applied to the vitellarium by the heating element generation and by the radiating mode, if can make heating element directly produce thermograde, then is to regulate warm field distribution effective means the most.
At present, at the crystal pulling method of resistive heating (referring to Chemical Engineering Science2004,59:1437 ~ 1457), heat-exchanging method is (referring to Journal of Crystal Growth1979,46:601-606), warm terraced method is (referring to Journal of Crystal Growth 1998,193:123-126) wait the simple wave loop heating elements that adopt in the crystal growing furnace, this heating element self does not produce thermograde more; In multiple hot body crystal pulling method, Bridgman method and the terraced method of two heating temperature, produce thermograde though can adopt graphite or silicon Mo to constitute a plurality of discrete heating elements, but it has increased the cost of equipment and the difficulty of control greatly, the stability of also influence temperature field.
Summary of the invention
The purpose of this utility model is to improve the design of above-mentioned existing heating element, make it can set up the required temperature field of growth gem-quality crystal quickly and easily, and increase the handiness of a temperature design, heating unit simply adjusted just go for the different sorts crystal growth, a kind of gradient type temperature field heating element that can set up suitable temperature field economic, quickly is provided.
The purpose of this utility model is achieved through the following technical solutions, a kind of gradient type temperature field heating element, it is characterized in that described heating element has the heating spoke that different thickness, cross section have different resistances of different radians up and down by the vertical section and constitutes, the partition grooves that is provided with on the heating spoke constitutes one or more current paths of heating element.
The heating spoke that described vertical section has the different resistances that different thickness, cross section have different radians up and down connects the space formation partition grooves that is provided with on the heating spoke of Lian Jieing successively at least from top to bottom successively by four groups.
Different resistance heating spokes are riveted each other or are welded to connect.
Each group heating spoke has two heating sheets at least, each piece heating sheet has identical internal diameter, each group heating sheet has different arc angles, each approximate trapezoid in piece heating sheet cross section, two hypotenuses are straight line or for curve, the upper surface that the lower surface of going up a heating sheet in a group most and next two of group leave the heating sheet in space each other formation " n " the type element that links to each other; Formation " m " type element again links to each other the lower surface of two " n " type elements that leave the space each other with the upper surface of a heating sheet in next group; With a plurality of " m " type element formation Heating tube that joins end to end.
Heating sheet arc angle in each group heating spoke is followed successively by from top to bottom≤90 ° ,≤45 ° ,≤90 ° ,≤180 °.
The height ratio of the heating sheet in each group heating spoke is 1:0.5-5:0.5-2:0.8-6.
The heating sheet vertical section of every group of heating spoke thickness transition up and down is straight line or is curve.
The utility model is in the same place by some heating sheets with certain vertical section and shape of cross section have reasonably been made up, form one or more current paths, part in different resistances produces different heats, so can produce certain thermograde in the vitellarium; And can be by the cross-sectional shape of adjusting the heating sheet and the distribution that highly comes to adjust neatly the temperature field, the utility model only needs a sleeving temperature control device when using in crystal growing furnace, not only simplified operation, reduced cost, also help and keep the stable of temperature field, the utility model is specially adapted to descent method, temperature ladder method, resistive heating crystal pulling method, Bridgman method, heat-exchanging method crystal growing furnace, also is applicable in other thermal treatment unit that needs temperature gradient distribution.
Description of drawings
Fig. 1 is the utility model sectional structure synoptic diagram;
Fig. 2 is the cross section structure synoptic diagram of several typical heating elements;
Axial temperature distribution schematic diagram in vitellarium when Fig. 3 is described several heating elements and is applied to crystal growing furnace by Fig. 2;
Among the figure, A, B, C, D are heating spoke, H
A, H
B, H
C, H
DBe heating spoke height, 1#, 2#, 3#, 4#, 5# represent several different vertical sections thickness, T
1, T
2, T
3, T
4, T
5Expression vertical section thickness, E is a partition grooves.
Embodiment
Further specify the utility model in conjunction with the accompanying drawings and embodiments, as shown in Figure 1, the utility model has the heating spoke that different thickness, cross section have different resistances of different radians up and down by the vertical section and constitutes, the partition grooves that is provided with on the heating spoke constitutes one or more current paths of heating element, adopts graphite or molybdenum or heating element of tungsten material.
Described hot body is made of four groups of heating spoke A, B, C, D at least, and their height is respectively H
A, H
B, H
C, H
D, respectively between 0 and the total height of heating element between, change height between them and recently realize adjustment temperature.Heating spoke A comprises that the polylith internal diameter is D, arc angle θ
A≤ 90 ° heating sheet, the cross-sectional shape approximate trapezoid: going up the length of side is L
1, the following length of side is L
2, and L
2〉=L
1, two hypotenuses can be straight line, also can camber line; Heating spoke B comprises that the polylith internal diameter is D, arc angle θ
B≤ 45 ° heating sheet, the cross-sectional shape approximate trapezoid: going up the length of side is L
2, the following length of side is L
3, and L
3〉=L
2, two hypotenuses can be straight line, also can be camber line; Heating spoke C comprises that the polylith internal diameter is D, arc angle θ
C≤ 90 ° heating sheet, the cross-sectional shape approximate trapezoid: going up the length of side is L
3, the following length of side is L
4, and L
4〉=L
3, two hypotenuses can be straight line, also can be camber line; Heating spoke D comprises that two internal diameters are D, arc angle θ
D≤ 180 ° heating sheet, the cross-sectional shape approximate trapezoid: going up the length of side is L
4, the following length of side is L
5, and L
5〉=L
4, two hypotenuses can be straight line, also can be camber line.Respectively the heating sheet lower surface among the heating spoke A is linked to each other with the upper surface of two heating spoke B, and keep leaving partition grooves E between two heating spoke B, form the element of a plurality of " n " type altogether; Lower surface with B heating sheet adjacent in two " n " type elements links to each other with the upper surface of element C again, forms the element of " m " type, and keeps leaving partition grooves E between " n " type element; So a plurality of " m " type element is joined end to end, form a Heating tube; The lower surface of two relative element C in the above-mentioned Heating tube is linked to each other with the upper surface of element D, so promptly form a complete heating element.Connection between the Heating element can be passed through modes such as welding, riveted joint, also can keep the connection portion not cut off by to complete Heating tube fluting the time and realize.
Embodiment 1:
Shown in 1# among Fig. 2, adopting the high purity graphite resistance heating material to make radius is R=60mm, the Heating tube of H=300mm.Trend according to partition grooves E among Fig. 1 is slotted to heating element, wherein: H
A=50mm, H
B=120mm, H
C=50mm, H
D=40mm; T
1=2.2mm, T
2=2.5mm, T
3=4mm, T
4=5mm, T
5=5mm.Wherein section thickness T2 is a straight line to the transition of T3.The heating element finished of preparation places crystal growing furnace, closes burner hearth, vacuumizes, and heats up after charging gas, and the temperature distribution situation in crystal growth district is as the 1# line among Fig. 3.
Embodiment 2:
Shown in 2# among Fig. 2, adopting the high purity graphite resistance heating material to make radius is R=60mm, the Heating tube of H=300mm.Trend according to partition grooves E among Fig. 1 is slotted to heating element, wherein: H
A=50mm, H
B=120mm, H
C=50mm, H
D=40mm; T
1=2.5mm, T
2=3mm, T
3=4.5mm, T
4=5mm, T
5=5mm.Wherein section thickness T2 is a concave to the transition of T3.The heating element finished of preparation places crystal growing furnace, closes burner hearth, vacuumizes, and heats up after charging gas, and the temperature distribution situation in crystal growth district is as 2# line among Fig. 3.
Embodiment 3:
Shown in 3# among Fig. 2, adopting the high purity graphite resistance heating material to make radius is R=60mm, the Heating tube of H=300mm.Trend according to partition grooves E among Fig. 1 is slotted to heating element, wherein: H
A=50mm, H
B=120mm, H
C=50mm, H
D=40mm; T
1=2.5mm, T
2=3mm, T
3=4.5mm, T
4=5mm, T
5=5mm.Wherein section thickness T2 is a straight line to the transition of T3.The heating element finished of preparation places crystal growing furnace, closes burner hearth, vacuumizes, and heats up after charging gas, and the temperature distribution situation in crystal growth district is as 3# line among Fig. 3.
Embodiment 4:
Shown in 4# among Fig. 2, adopting the high purity graphite resistance heating material to make radius is R=60mm, the Heating tube of H=300mm.Trend according to partition grooves E among Fig. 1 is slotted to heating element, wherein: H
A=50mm, H
B=120mm, H
C=50mm, H
D=40mm; T
1=2.5mm, T
2=3mm, T
3=4.5mm, T
4=5mm, T
5=5mm.Wherein section thickness T2 is a convex line to the transition of T3.The heating element finished of preparation places crystal growing furnace, closes burner hearth, vacuumizes, and heats up after charging gas, and the temperature distribution situation in crystal growth district is as 4# line among Fig. 3.
Embodiment 5:
Shown in 5# among Fig. 2, adopting the high purity graphite resistance heating material to make radius is R=60mm, the Heating tube of H=300mm.Trend according to partition grooves E among Fig. 1 is slotted to heating element, wherein: H
A=50mm, H
B=120mm, H
C=50mm, H
D=40mm; T
1=3mm, T
2=3.5mm, T
3=5mm, T
4=5mm, T
5=5mm.Wherein section thickness T2 is a straight line to the transition of T3.The heating element finished of preparation places crystal growing furnace, closes burner hearth, vacuumizes, and heats up after charging gas, and the temperature distribution situation in crystal growth district is as 5# line among Fig. 3.
Claims (7)
1. gradient type temperature field heating element, it is characterized in that described heating element has the heating spoke that different thickness, cross section have different resistances of different radians up and down by the vertical section and constitutes, the partition grooves that is provided with on the heating spoke constitutes one or more current paths of heating element.
2. gradient type temperature field heating element according to claim 1, it is characterized in that the heating spoke that described vertical section has the different resistances that different thickness, cross section have different radians up and down connects the space formation partition grooves that is provided with on the heating spoke of Lian Jieing successively at least from top to bottom successively by four groups.
3. gradient type temperature field heating element according to claim 2 is characterized in that different resistances heating spokes rivet each other or be welded to connect.
4. gradient type temperature field heating element according to claim 2, it is characterized in that each group heating spoke has two heating sheets at least, each piece heating sheet has identical internal diameter, each group heating sheet has different arc angles, each approximate trapezoid in piece heating sheet cross section, two hypotenuses are straight line or for curve, the upper surface that the lower surface of going up a heating sheet in a group most and next two of group leave the heating sheet in space each other formation " n " the type element that links to each other; Formation " m " type element again links to each other the lower surface of two " n " type elements that leave the space each other with the upper surface of a heating sheet in next group; With a plurality of " m " type element formation Heating tube that joins end to end.
5. according to claim 2 or 4 described gradient type temperature field heating elements, it is characterized in that the heating sheet arc angle in each group heating spoke is followed successively by from top to bottom≤90 ° ,≤45 ° ,≤90 ° ,≤180 °.
6. according to claim 2 or 4 described gradient type temperature field heating elements, it is characterized in that the height ratio of the heating sheet in each group heating spoke is 1:0.5-5:0.5-2:0.8-6.
7. according to claim 2 or 4 described gradient type temperature field heating elements, the heating sheet vertical section that it is characterized in that every group of heating spoke thickness transition up and down is straight line or is curve.
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CNU2008201168584U CN201198501Y (en) | 2008-05-12 | 2008-05-12 | Gradient temperature field heating element |
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CNU2008201168584U CN201198501Y (en) | 2008-05-12 | 2008-05-12 | Gradient temperature field heating element |
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102560638A (en) * | 2010-12-16 | 2012-07-11 | 天津津航技术物理研究所 | Equipment For Preparing Zinc Selenide/zinc Sulfide Optical Material, Furnace, Heater For The Furnace |
CN102609017A (en) * | 2012-03-01 | 2012-07-25 | 大连理工大学 | Heating device and method capable of producing controllable temperature gradient field on metal wing structure |
CN102828237A (en) * | 2011-06-17 | 2012-12-19 | 天津津航技术物理研究所 | Apparatus for preparing zinc selenide/zinc sulfide lamination polycrystal optical material |
CN103160913A (en) * | 2011-12-18 | 2013-06-19 | 洛阳金诺机械工程有限公司 | Temperature gradient controlling device of crystal growth and method thereof |
-
2008
- 2008-05-12 CN CNU2008201168584U patent/CN201198501Y/en not_active Expired - Fee Related
Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102560638A (en) * | 2010-12-16 | 2012-07-11 | 天津津航技术物理研究所 | Equipment For Preparing Zinc Selenide/zinc Sulfide Optical Material, Furnace, Heater For The Furnace |
CN102828237A (en) * | 2011-06-17 | 2012-12-19 | 天津津航技术物理研究所 | Apparatus for preparing zinc selenide/zinc sulfide lamination polycrystal optical material |
CN103160913A (en) * | 2011-12-18 | 2013-06-19 | 洛阳金诺机械工程有限公司 | Temperature gradient controlling device of crystal growth and method thereof |
CN102609017A (en) * | 2012-03-01 | 2012-07-25 | 大连理工大学 | Heating device and method capable of producing controllable temperature gradient field on metal wing structure |
CN102609017B (en) * | 2012-03-01 | 2014-06-11 | 大连理工大学 | Heating device and method capable of producing controllable temperature gradient field on metal wing structure |
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C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
C17 | Cessation of patent right | ||
CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20090225 Termination date: 20110512 |