CN204529321U - For the chassis assembly of polycrystalline silicon reducing furnace - Google Patents

Abstract

The utility model discloses a kind of chassis assembly for polycrystalline silicon reducing furnace, the described chassis assembly for polycrystalline silicon reducing furnace comprises: chassis body, six helical flow paths of the outer peripheral edge from chassis body described in the center rotation direction of described chassis body are limited with in described chassis body, described chassis body is provided with the cooling liquid inlet and at least six cooling liquid outlets that are communicated with six described helical flow paths, and described cooling liquid inlet is positioned at the center of described chassis body; Multiple electrode holder, multiple described electrode holder is arranged in described chassis body; Multiple inlet pipe and multiple vapor pipe, multiple described inlet pipe and multiple described vapor pipe are arranged in described chassis body.Have that cooling liquid flowing dynamic resistance is little according to the chassis assembly for polycrystalline silicon reducing furnace of the utility model embodiment, good cooling results, radial temperature profile evenly, not easily produce the advantage such as temperature stress and distortion.

Description

For the chassis assembly of polycrystalline silicon reducing furnace

Technical field

The utility model relates to technical field of polysilicon production, in particular to a kind of chassis assembly for polycrystalline silicon reducing furnace.

Background technology

Polycrystalline silicon reducing furnace is the nucleus equipment of output the finished product in production of polysilicon, is also the key link of decision systems production capacity, energy consumption.Small-sized polycrystalline silicon reducing furnace (as 12 to rod, 18 to excellent reduction furnace etc.) the general energy consumption of production unit weight product is higher, single furnace output is relatively low, more and more be not suitable with current market demands. along with development and the raising of polysilicon equipment level, large-scale reduction furnace is continually developed, occurred 36 to rod, 48 to rod even 60 to excellent reduction furnace.

Large polycrystalline silicon reducing furnace in correlation technique, although solve the problem of some output and energy consumption, but along with the maximization of equipment and complicated, cooling liquid flowing dynamic resistance in its chassis increases, cause cooling performance poor, and due to the flow process of cooling fluid longer, chassis radial temperature profile is uneven, causes chassis to produce temperature stress and distortion.

Utility model content

The utility model is intended to solve one of above-mentioned technical problem in correlation technique at least to a certain extent.For this reason, the utility model proposes a kind of chassis assembly for polycrystalline silicon reducing furnace, this chassis assembly being used for polycrystalline silicon reducing furnace has that cooling liquid flowing dynamic resistance is little, good cooling results, radial temperature profile evenly, not easily produce the advantage such as temperature stress and distortion.

For achieving the above object, according to the utility model proposes a kind of chassis assembly for polycrystalline silicon reducing furnace, the described chassis assembly for polycrystalline silicon reducing furnace comprises: chassis body, six helical flow paths of the outer peripheral edge from chassis body described in the center rotation direction of described chassis body are limited with in described chassis body, described chassis body is provided with the cooling liquid inlet and at least six cooling liquid outlets that are communicated with six described helical flow paths, and described cooling liquid inlet is positioned at the center of described chassis body; Multiple electrode holder, multiple described electrode holder is arranged in described chassis body; Multiple inlet pipe and multiple vapor pipe, multiple described inlet pipe and multiple described vapor pipe are arranged in described chassis body.

Have that cooling liquid flowing dynamic resistance is little according to the chassis assembly for polycrystalline silicon reducing furnace of the present utility model, good cooling results, radial temperature profile evenly, not easily produce the advantage such as temperature stress and distortion.

In addition, following additional technical characteristic can also be had according to the chassis assembly for polycrystalline silicon reducing furnace of the present utility model:

The length of six described helical flow paths is equal.

Six described helical flow paths are coiled into seven layers along the radial transmission line of described chassis body.

Described chassis body comprises: chassis flange; Upper plate, described upper plate is located in the flange of described chassis; Lower shoe, described lower shoe to be located in the flange of described chassis and to be positioned at below described upper plate; Median septum, described median septum to be located in the flange of chassis and between described upper plate and described lower shoe, and described median septum and described upper plate and described chassis flange limit cooling chamber; Six flow deflectors, six described flow deflectors to be located in described cooling chamber and in described cooling chamber, to limit six described helical flow paths.

Six described flow deflectors are welded on described median septum.

The described inlet pipe of vicinity of described flow deflector, described vapor pipe and described electrode holder place are respectively equipped with segmental arc.

Each described flow deflector is provided with some communicating apertures.

The described chassis assembly for polycrystalline silicon reducing furnace also comprises and is located at cooling fluid inlet pipe in described chassis body and at least six cooling fluids go out pipe, described cooling fluid inlet pipe is arranged on the center of described chassis body and is communicated with described cooling liquid inlet, and described cooling fluid goes out pipe and is arranged on the outer peripheral edge place of described chassis body and is communicated with corresponding described cooling liquid outlet respectively.

Cooling fluid described in any one goes out the vertex of vertex higher than described cooling fluid inlet pipe of pipe.

The described inlet pipe being positioned at described chassis body center in multiple described inlet pipe is nested in described cooling fluid inlet pipe, and described vapor pipe is at least six and is nested in corresponding described cooling fluid respectively to go out in pipe.

Accompanying drawing explanation

Fig. 1 is the axial sectional view of the chassis assembly for polycrystalline silicon reducing furnace according to the utility model embodiment.

Fig. 2 is the radial cross-section of the chassis assembly for polycrystalline silicon reducing furnace according to the utility model embodiment.

Reference numeral: go out pipe 600 for the chassis assembly 10 of polycrystalline silicon reducing furnace, chassis body 100, helical flow path 110, cooling liquid inlet 120, cooling liquid outlet 130, chassis flange 140, upper plate 150, lower shoe 160, median septum 170, cooling chamber 180, flow deflector 190, segmental arc 191, electrode holder 200, inlet pipe 300, vapor pipe 400, cooling fluid inlet pipe 500, cooling fluid.

Embodiment

Be described below in detail embodiment of the present utility model, the example of described embodiment is shown in the drawings, and wherein same or similar label represents same or similar element or has element that is identical or similar functions from start to finish.Be exemplary below by the embodiment be described with reference to the drawings, be intended to for explaining the utility model, and can not be interpreted as restriction of the present utility model.

Below with reference to the accompanying drawings the chassis assembly 10 for polycrystalline silicon reducing furnace according to the utility model embodiment is described.

As depicted in figs. 1 and 2, chassis body 100, multiple electrode holder 200, multiple inlet pipe 300 and multiple vapor pipe 400 is comprised according to the chassis assembly 10 for polycrystalline silicon reducing furnace of the utility model embodiment.

Six helical flow paths 110 are limited with in chassis body 100, six helical flow paths 110 are from the outer peripheral edge of the center rotation direction chassis body 100 of chassis body 100, chassis body 100 is provided with the cooling liquid inlet 120 and at least six cooling liquid outlets 130 that are communicated with six helical flow paths 110, namely cooling liquid inlet 120 respectively six helical flow paths 110 be communicated with, and each helical flow path 110 is communicated with at least one cooling liquid outlet 130, wherein, cooling liquid inlet 120 is positioned at the center of chassis body 100.Multiple electrode holder 200 is arranged in chassis body 100.Multiple inlet pipe 300 and multiple vapor pipe 400 to be arranged in chassis body 100 and to run through chassis body 100 (above-below direction is as shown in the arrow A in accompanying drawing) along the vertical direction.

According to the chassis assembly 10 for polycrystalline silicon reducing furnace of the utility model embodiment, by arranging six helical flow paths 110 from the outer peripheral edge of the center rotation direction chassis body 100 of chassis body 100 in chassis body 100, and the cooling liquid inlet 120 be communicated with six helical flow paths 110 is respectively set in the center of chassis body 100, such cooling fluid can enter six helical flow paths 110 respectively by cooling liquid inlet 120, carries out pressure cooling to the upper surface of chassis body 100, multiple inlet pipe 300, multiple vapor pipe 400 and multiple electrode holder 200.Owing to arranging six helical flow paths 110 in chassis body 100, make the flow process of each helical flow path 110 shorter, decrease the resistance to flow of cooling fluid, improve cooling performance, and it is excessive to avoid chassis body 100 radial temperature difference, be conducive to preventing chassis body 100 from producing temperature stress and distortion.Therefore, have that cooling liquid flowing dynamic resistance is little according to the chassis assembly 10 for polycrystalline silicon reducing furnace of the utility model embodiment, good cooling results, radial temperature profile evenly, not easily produce the advantage such as temperature stress and distortion.

Below with reference to the accompanying drawings the chassis assembly 10 for polycrystalline silicon reducing furnace according to the utility model specific embodiment is described.

In specific embodiments more of the present utility model, as depicted in figs. 1 and 2, chassis body 100, multiple electrode holder 200, multiple inlet pipe 300 and multiple vapor pipe 400 is comprised according to the chassis assembly 10 for polycrystalline silicon reducing furnace of the utility model embodiment.

Further, the length of six helical flow paths 110 is equal, and the width at the equal length place of six helical flow paths 110 is equal.The homogeneity of chassis body 100 radial temperature can be improved thus further, thus prevent chassis body 100 from producing temperature stress and distortion further.

Alternatively, as shown in Figure 1, six helical flow paths 110 are coiled into seven layers along the radial transmission line of chassis body 100, and cooling liquid outlet 130 is arranged on the outer peripheral edge place of chassis body 100, and cooling fluid is discharged by after the heart channel of Hang-Shaoyin helical flow path 110 in chassis body 100.

In concrete examples more of the present utility model, as depicted in figs. 1 and 2, chassis body 100 comprises chassis flange 140, upper plate 150, lower shoe 160, median septum 170.Chassis flange 140 is for connecting body of heater.Upper plate 150, lower shoe 160 and median septum 170 are all located in chassis flange 140, wherein lower shoe 160 below upper plate 150 and median septum 170 between upper plate 150 and lower shoe 160, median septum 170 limits cooling chamber 180 with upper plate 150 and chassis flange 140.Inlet pipe 300 and vapor pipe 400 run through upper plate 150, median septum 170 and lower shoe 160.Can reduce lower portion of furnace body inlet pipe quantity thus, simplified apparatus is installed and piping layout.

In order to arrange helical flow path 110 in above-mentioned chassis body 100, six flow deflectors 190 can being located in cooling chamber 180 and in cooling chamber 180, limiting six helical flow paths 110, namely cooling chamber 180 can be made up of jointly six helical flow paths 110.For improving the stability of flow deflector 190 in cooling chamber 180, six flow deflectors 190 can be welded on the upper surface of median septum 170.

Further, as shown in Figure 1, the contiguous inlet pipe 300 of each flow deflector 190, vapor pipe 400 and electrode holder 200 place are respectively equipped with segmental arc 191, the cross-sectional area of helical flow path 110 can be kept substantially constant with the flow speed stability ensureing cooling fluid on the one hand thus, can avoid on the other hand occurring cooling dead angle and affecting cooling performance.

That the quantity of the segmental arc 191 on each flow deflector 190 and position and can require to arrange according to practical application with it will be appreciated by those skilled in the art that.

Advantageously, each flow deflector 190 is provided with the spaced multiple communicating aperture (not shown) of length direction along flow deflector 190, particularly, each flow deflector 190 can be provided with 3-10 described communicating aperture, communicating aperture described in these can be communicated with the helical flow path 110 of flow deflector 190 both sides, cooling fluid in two adjacent helical flow paths 110 is circulated mutually, thus avoids producing coolant flow dead band.

In specific embodiments more of the present utility model, as shown in Figure 2, chassis assembly 10 for polycrystalline silicon reducing furnace also comprises a cooling fluid inlet pipe 500 and at least six cooling fluids go out pipe 600, and cooling fluid inlet pipe 500 and cooling fluid go out pipe 600 and to be all located in chassis body 100 and to run through lower shoe 160 and median septum 170.Wherein, cooling fluid inlet pipe 500 is arranged on the center of chassis body 100 and is communicated with cooling liquid inlet 120, and cooling fluid goes out pipe 600 and is arranged on the outer peripheral edge place of chassis body 100 equally spacedly along the circumference of chassis body 100 and is communicated with corresponding cooling liquid outlet 130 respectively.By arranging cooling fluid inlet pipe 500 and cooling fluid goes out pipe 600, the input and output of cooling fluid can be facilitated.

Alternatively, as depicted in figs. 1 and 2, the inlet pipe 300 being positioned at chassis body 100 center in multiple inlet pipe 300 is nested in cooling fluid inlet pipe 500, and vapor pipe 400 is at least six and is nested in corresponding cooling fluid respectively to go out in pipe 600.The structure of chassis assembly 10 can be simplified like this, and the quantity of chassis assembly 10 appearance pipeline can be reduced, thus the space that reduction pipeline takies in chassis body 100.

Advantageously, as shown in Figure 2, any one cooling fluid goes out the vertex of vertex higher than cooling fluid inlet pipe 500 of pipe 600, can make thus to ensure a certain amount of cooling fluid at any time in cooling chamber 180.

In description of the present utility model, it will be appreciated that, term " " center ", " longitudinal direction ", " transverse direction ", " length ", " width ", " thickness ", " on ", D score, " front ", " afterwards ", " left side ", " right side ", " vertically ", " level ", " top ", " end " " interior ", " outward ", " clockwise ", orientation or the position relationship of the instruction such as " counterclockwise " are based on orientation shown in the drawings or position relationship, only the utility model and simplified characterization for convenience of description, instead of indicate or imply that the device of indication or element must have specific orientation, with specific azimuth configuration and operation, therefore can not be interpreted as restriction of the present utility model.

In addition, term " first ", " second " only for describing object, and can not be interpreted as instruction or hint relative importance or imply the quantity indicating indicated technical characteristic.Thus, be limited with " first ", the feature of " second " can express or impliedly comprise one or more these features.In description of the present utility model, the implication of " multiple " is at least two, such as two, three etc., unless otherwise expressly limited specifically.

In the utility model, unless otherwise clearly defined and limited, the term such as term " installation ", " being connected ", " connection ", " fixing " should be interpreted broadly, and such as, can be fixedly connected with, also can be removably connect, or integral; Can be mechanical connection, also can be electrical connection; Can be directly be connected, also indirectly can be connected by intermediary, can be the connection of two element internals or the interaction relationship of two elements.For the ordinary skill in the art, the concrete meaning of above-mentioned term in the utility model can be understood as the case may be.

In the utility model, unless otherwise clearly defined and limited, fisrt feature second feature it " on " or D score can comprise the first and second features and directly contact, also can comprise the first and second features and not be directly contact but by the other characterisation contact between them.And, fisrt feature second feature " on ", " top " and " above " comprise fisrt feature directly over second feature and oblique upper, or only represent that fisrt feature level height is higher than second feature.Fisrt feature second feature " under ", " below " and " below " comprise fisrt feature immediately below second feature and tiltedly below, or only represent that fisrt feature level height is less than second feature.

In the description of this specification sheets, specific features, structure, material or feature that the description of reference term " embodiment ", " some embodiments ", " example ", " concrete example " or " some examples " etc. means to describe in conjunction with this embodiment or example are contained at least one embodiment of the present utility model or example.In this manual, to the schematic representation of above-mentioned term not must for be identical embodiment or example.And the specific features of description, structure, material or feature can combine in an appropriate manner in any one or more embodiment or example.In addition, the different embodiment described in this specification sheets or example can carry out engaging and combining by those skilled in the art.

Although illustrate and described embodiment of the present utility model above, be understandable that, above-described embodiment is exemplary, can not be interpreted as restriction of the present utility model, those of ordinary skill in the art can change above-described embodiment, revises, replace and modification in scope of the present utility model.

Claims (10)

1. for a chassis assembly for polycrystalline silicon reducing furnace, it is characterized in that, comprising:

Chassis body, six helical flow paths of the outer peripheral edge from chassis body described in the center rotation direction of described chassis body are limited with in described chassis body, described chassis body is provided with the cooling liquid inlet and at least six cooling liquid outlets that are communicated with six described helical flow paths, and described cooling liquid inlet is positioned at the center of described chassis body;

Multiple electrode holder, multiple described electrode holder is arranged in described chassis body;

Multiple inlet pipe and multiple vapor pipe, multiple described inlet pipe and multiple described vapor pipe are arranged in described chassis body.

2. the chassis assembly for polycrystalline silicon reducing furnace according to claim 1, is characterized in that, the length of six described helical flow paths is equal.

3. the chassis assembly for polycrystalline silicon reducing furnace according to claim 1, is characterized in that, six described helical flow paths are coiled into seven layers along the radial transmission line of described chassis body.

4. the chassis assembly for polycrystalline silicon reducing furnace according to claim 1, is characterized in that, described chassis body comprises:

Chassis flange;

Upper plate, described upper plate is located in the flange of described chassis;

Lower shoe, described lower shoe to be located in the flange of described chassis and to be positioned at below described upper plate;

Median septum, described median septum to be located in the flange of chassis and between described upper plate and described lower shoe, and described median septum and described upper plate and described chassis flange limit cooling chamber;

Six flow deflectors, six described flow deflectors to be located in described cooling chamber and in described cooling chamber, to limit six described helical flow paths.

5. the chassis assembly for polycrystalline silicon reducing furnace according to claim 4, is characterized in that, six described flow deflectors are welded on described median septum.

6. the chassis assembly of polycrystalline silicon reducing furnace according to claim 4, is characterized in that, the described inlet pipe of vicinity of described flow deflector, described vapor pipe and described electrode holder place are respectively equipped with segmental arc.

7. the chassis assembly of polycrystalline silicon reducing furnace according to claim 4, is characterized in that, each described flow deflector is provided with some communicating apertures.

8. the chassis assembly for polycrystalline silicon reducing furnace according to claim 1, it is characterized in that, also comprise and be located at cooling fluid inlet pipe in described chassis body and at least six cooling fluids go out pipe, described cooling fluid inlet pipe is arranged on the center of described chassis body and is communicated with described cooling liquid inlet, and described cooling fluid goes out pipe and is arranged on the outer peripheral edge place of described chassis body and is communicated with corresponding described cooling liquid outlet respectively.

9. the chassis assembly for polycrystalline silicon reducing furnace according to claim 8, is characterized in that, cooling fluid described in any one goes out the vertex of vertex higher than described cooling fluid inlet pipe of pipe.

10. the chassis assembly for polycrystalline silicon reducing furnace according to claim 8, it is characterized in that, the described inlet pipe being positioned at described chassis body center in multiple described inlet pipe is nested in described cooling fluid inlet pipe, and described vapor pipe is at least six and is nested in corresponding described cooling fluid respectively to go out in pipe.