CN203700442U - Heating device for annular component and annular cavity of heating device - Google Patents

Heating device for annular component and annular cavity of heating device Download PDF

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Publication number
CN203700442U
CN203700442U CN201320880768.3U CN201320880768U CN203700442U CN 203700442 U CN203700442 U CN 203700442U CN 201320880768 U CN201320880768 U CN 201320880768U CN 203700442 U CN203700442 U CN 203700442U
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China
Prior art keywords
annular
annular housing
air flow
air
water conservancy
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CN201320880768.3U
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Chinese (zh)
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马盛骏
刘承前
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Beijing Goldwind Science and Creation Windpower Equipment Co Ltd
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Beijing Goldwind Science and Creation Windpower Equipment Co Ltd
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Abstract

The utility model provides a heating device for an annular component. The heating device is used for heating the annular component through hot air, comprises an air heater and a fan and further comprises an annular cavity for accommodating the annular component, wherein an air inlet and an air outlet are formed in the outer wall of the annular cavity, the air heater is used for heating air, and the air enters the air inlet through the fan, passes through an air passage in the annular cavity and then is discharged from the air outlet. The heating device provided by the utility model shortens the air circulating path, so that the air passage can be concentrated nearby the annular component, and then the heat exchange is more effective. In addition, the consumption of materials for manufacturing the heating device is reduced, and the manufacturing cost is reduced. Moreover, the utility model also correspondingly provides the annular cavity of the heating device. The annular cavity accommodates the heated annular component, and the air inlet and the air outlet are formed in the outer wall of the annular cavity.

Description

A kind of heating unit of annular element and annular housing thereof
Technical field
The utility model relates to a kind of heating unit and annular housing thereof, relates in particular to the heating unit and the annular housing thereof that as heat exchange medium, annular element are heated using gas.
Background technology
For example, for the heating (in bearing hot jacket method, need to heat large-scale bearing) of large-scale annular element, generally adopt the mode of oil bath, electromagnetic induction eddy current heating and air heating.Wherein, the mode of air heating is used more.Take the air-heating furnace that uses in bearing hot jacket method as example, this air-heating furnace, using warm air as heat-transfer medium, heats hot jacket bearing parts surface, and type of heating, take transmission of heat by convection as main, is aided with radiative transfer.
As shown in Figure 1, the structural representation of its air-heating furnace that is prior art, it has shown the structure of the typical parts of bearings hot jacket process furnace using in current industry.This process furnace is divided at the bottom of bell 81 and stove basin two portions Shang Xia 82.The process furnace body of prior art is formed by shaped steel and Plate Welding, and furnace lining uses engineering thermal insulation material (aluminum silicate fiber rock wool etc.) to be filled between inner bag and protective case by the method for tiling and lay-up, makes adiabatic heat-insulation use as furnace lining.The top center position of bell 81 is provided with motor 83 for stove, and this motor is fixed by flange, and stove drives centrifugal blower 86 as the mobile power of air cycle with motor.Centrifugal blower 86 belows arrange flow deflector, and flow deflector and bell 81 inwalls form " spoke circulation road " part of the air flow channel on top.At the bottom of stove basin in 82, be provided with the annular chin spoiler 85 coaxial with the vertical portion of baffle upper plate 84, bell 81 with at the bottom of stove basin 82 and seam after, baffle upper plate 84 and chin spoiler 85 can dock formation annular air-flow path in inside.At the bottom of stove basin, 82 adopt channel-section steel to make underframe, strengthen temperature uniformity.Chin spoiler 85 leaves contour gap with 82 inwalls at the bottom of stove basin, flows into the region (as shown in Fig. 1 arrow) at heated parts of bearings place for the air-flow from bell 81 through " annular gap " from 82 " contour gap " at the bottom of stove basin.In the annular region that baffle upper plate 84 and chin spoiler 85 surround, after parts of bearings surface heat release, be flowed to the air suction inlet of centrifugal blower 86.Conventionally the electrical heating element that at the interior spoke circulation road of bell 81, some amount is set, as well heater 87, is used for heating fluidizing air, and electrical heating element distributes along even circumferential.Heated large size bearing parts are placed at the bottom of stove basin on 82 in the mode of multi-point support, and coaxial and equidistantly with chin spoiler 85.
Be more than the basic structure of the air-heating furnace of prior art, contriver realizing in process of the present utility model, finds that air-heating furnace of the prior art exists following defect:
1) there is waste in air flow path
Along with the increase of bearing radial dimension, the annular region of parts of bearings also can increase with interior space, central zone, when bearing radial dimension increases to after the order of magnitude of several meters, in the time that such parts of bearings is heated, space, central zone is exactly unnecessary for the convective heat exchange between bearing surface and warm air, exists huge waste on air flow path.Meanwhile, along with the increase of parts of bearings size, in order to make air-flow fully mobile, the drive-motor power of fan is also along with increase, power consumption also increase.
2) on the material of manufacture heating unit, there is waste
From process furnace axially, be all unnecessary from bell 81 to the materials consumption of furnace hearth plate 82 central zones, the heat-insulating material especially using in these regions.Meanwhile, because integrally-built change is large, for proof strength, the size of the main beam structure of process furnace body also can increase, and the material expending can further increase, thus the manufacturing cost significantly improving.
utility model content
The purpose of this utility model is, a kind of heating unit and annular housing thereof of annular element is provided, and to reduce the waste on air flow path, and saves the material of manufacturing heating unit.
To achieve these goals, the utility model provides a kind of heating unit of annular element, this heating unit heats described annular element by hot gas flow, it comprises flow type calorifier and blower fan, this heating unit also comprises the annular housing that holds described annular element, on the outer wall of this annular housing, be provided with air flow inlet and air stream outlet, described flow type calorifier heats described air-flow, described blower fan makes described air-flow enter described air flow inlet, after the air flow path in described annular housing, discharge from described air stream outlet.
The heating unit of annular element of the present utility model is by adopting the structure of annular housing, save the airflow path of the central zone surrounding in annular element, air flow path can be concentrated near annular element, thereby make heat exchange more effective, reduced thermal waste.And, reduce the materials consumption of manufacturing heating unit, reduce manufacturing cost.
The utility model also provides a kind of annular housing of heating unit, and this annular housing holds heated annular element, is provided with air flow inlet and air stream outlet on the outer wall of this annular housing.
Compared with the furnace chamber of the annular housing of heating unit of the present utility model and the process furnace of prior art, save the airflow path of the central zone surrounding in annular element, air flow path can be concentrated near annular element, thereby make heat exchange more effective, reduced thermal waste.In addition, compared with the furnace chamber of the process furnace of prior art, reduce the materials consumption of manufacturing furnace chamber body, reduced manufacturing cost.
accompanying drawing explanation
Fig. 1 is the structural representation of the air-heating furnace of prior art.
Fig. 2 is the structural representation of the heating unit of the annular element of the utility model embodiment mono-.
Fig. 3 is the structural representation of the heating unit of the annular element of the utility model embodiment bis-.
Fig. 4 is the plan structure schematic diagram of the water conservancy diversion spiral fin of the heating unit of the annular element of the utility model embodiment bis-.
Fig. 5 is the perspective view of the water conservancy diversion spiral fin of the heating unit of the annular element of the utility model embodiment bis-.
Fig. 6 is the partial cutaway schematic of the annular housing that is provided with water conservancy diversion spiral fin of the utility model embodiment tri-.
Fig. 7 is the schematic diagram of the variation relation between the surface coefficient of heat transfer of the utility model embodiment tri-and the temperature of hot gas flow.
Embodiment
The one-piece construction of the heating unit of the annular element of the utility model to prior art is improved, and by the structural modification annular housing structure of the process furnace of existing disc type, and has carried out on this basis further design and improvement.Below, by embodiment, the heating unit of annular element of the present utility model is elaborated.
Embodiment mono-
As shown in Figure 2, it is the structural representation of the heating unit of the annular element of the utility model embodiment mono-.The heating unit of the annular element of the present embodiment, by hot gas flow, annular element is heated, it comprises flow type calorifier 1 and blower fan 2, also comprise the annular housing 3 that holds annular element 4, on the outer wall of this annular housing, be provided with air flow inlet 301 and air stream outlet 302, flow type calorifier 1 heats air-flow, and blower fan 2 makes air-flow enter air flow inlet 301, after the air flow path in annular housing, discharge from air stream outlet 302.For the internal structure of annular housing 3 is shown, in Fig. 2, remove the half of upper annular housing 31, to illustrate, annular element 4 is put into the state after annular housing 3.
The structure of the heating unit of the present embodiment has adopted annular housing, compared with the process furnace of prior art, save the airflow path of the central zone surrounding in annular element 4, air flow path can be concentrated near annular element 4, thereby make heat exchange more effective, reduced thermal waste.And owing to having adopted annular housing, reduce in airflow path, the power of the blower fan of required driving air current flow has also reduced.In addition, owing to adopting annular housing, in one-piece construction, save in the process furnace of prior art corresponding to 82 part (as shown in Figure 1) at the bottom of the bell 81 of annular element 4 central zones and stove basin, thereby reduced the materials consumption of manufacturing heating unit, reduced manufacturing cost.And, on manufacturing, be not subject to the restriction of the radial dimension etc. of annular element, greatly reduce manufacturing cost, can make manufacturing cost materials consumption reduce half.
The annular housing of embodiment of the present utility model can adopt any openable structure or can disassemblying structure, put into the inner chamber of annular housing 3 as long as can make heated annular element 4, in addition, also can customize separately according to indivedual annular elements, the utility model does not limit this.
Preferably, annular housing 3 is engaged and is formed by upper annular housing 31 and lower annular housing 32.As shown in Figure 2, in the present embodiment, annular housing 3 is circular, and the cross section of annular housing 3 is circular, along the radially plane at place of annular housing, in the vertical direction, it is U-shaped upper annular housing 31 and lower annular housing 32 that annular housing is split as to two cross sections.
In the time that reality is used, upper annular housing 31 is removed, annular element 4 is put into the inner chamber of lower annular housing 32, and then upper annular housing 31 and lower annular housing 32 are engaged to the airtight annular housing 3 of formation.More preferably, upper annular housing 31 is engaged and is formed by multiple annular Cavity units, and lower annular housing 32 is engaged and formed by multiple lower annular housings unit.When use, multiple annular Cavity units and lower annular housing unit are engaged, form complete annular housing.For example, can be by upper annular housing 31 the annular circumferential direction along annular housing 3, be split as two identical semicircular annular Cavity units, the state shown in Fig. 2, can be regarded as the state that has removed annular Cavity unit on one of them.In like manner, lower annular housing 32 also can be split as two identical lower annular housing unit.
By such opening or disassembled structure, be convenient to annular element 4 to put into the inside of annular housing 3, meanwhile, be also convenient to transportation, the process furnace radial dimension that has solved prior art exceedes the problem that the restriction of road surface transportation width requires, and meets the requirement of portable transportation.
In addition, air flow inlet 301 and air stream outlet 302 can be arranged on any position of annular housing 3, and flow type calorifier 1 and blower fan 2 positions also can arrange flexibly, can be in the outside of annular housing, the inside that also can be arranged on as required annular housing, can also arrange multiple as required.
Preferably, flow type calorifier 1 heated air-flow enter the air flow path of annular housing at air-flow before,, flow type calorifier 1 is arranged on annular housing outside, or be arranged on annular housing inside corresponding to air flow inlet 301 places, in the case of forming the air flow path of sealing and circulating, annular housing inside corresponding to air stream outlet 302 places also can be set.Adopt such structure, comparatively simple for air-flow type of heating, flow type calorifier can not take the space of the air flow path of annular housing inside.
More preferably, as shown in Figure 2, air flow inlet 301 and air stream outlet 302 can be arranged on the outer wall of inner side of annular housing, flow type calorifier 1 and blower fan 2 are arranged on the inner side of annular housing, between inner chamber, air stream outlet 302, blower fan 2 and the flow type calorifier 1 of air flow inlet 301, annular housing, form airtight airflow circulation passage.Adopt such structure, make the circulating path minimum of air-flow, can effectively utilize heat energy, fully realize heat exchange.
In addition,, in annular housing, between air flow inlet 301 and air stream outlet 302, form two identical air flow paths of length and be advisable.For example, as shown in Figure 2, air flow inlet 301 and air stream outlet 302 are arranged on the outer wall of annular housing 3 inner sides, and on the same diameter in annular housing 3, like this, from air flow inlet 301 to air stream outlet 302, axially form two air flow paths that length is identical along annular element 4.Adopt such structure, the gas flow temperature in two air flow paths changes, air-flow velocity is basic identical, is convenient to unification air-flow is controlled, and also makes two annular elements in air flow path be subject to thermal conditions consistent.
In the present embodiment, can adopt air as heat exchange medium, can also be provided with airflow filtering device at air stream outlet 302 places, using the air after filtering as heat transmission medium, can protect bearing surface not contaminated.
In addition, the annular housing of the present embodiment can be any annulars such as ellipse, rectangle, trilateral, thereby can heat for the special annular element 4 of various non-annulars.Gas as heat exchange medium is not limited to air, for example, can also use Sweet natural gas etc. as high-temperature heat-transfer medium.In addition,, for the filtration of air-flow, also can adopt other gas-solid separation equipment.
In addition, the heating unit of present embodiment can adopt Thermo Isolation Technique, for example, adopts high thermal insulation material to manufacture annular housing etc.Thereby improve the heating efficiency of ground annular element 4, further save the energy.
Embodiment bis-
Embodiment of the present utility model, except the improvement in one-piece construction, is also further improved the inside of annular housing.
Fig. 3 is the structural representation of the heating unit of the annular element of the utility model embodiment bis-, as shown in Figure 3, on the basis of embodiment mono-, in annular housing 3, be provided with baffle, this baffle makes described air-flow equably along the apparent motion of described annular element.By at the interior baffle that arranges of annular housing 3, thereby the flow pattern of air-flow is controlled, thus, annular element is heated evenly, and improve heating efficiency.
Preferably, described baffle is water conservancy diversion spiral fin 5, the hot blast track that makes to enter in annular housing by this water conservancy diversion spiral fin 5 becomes the large size bearing parts as shown in Figure 3 around annular element 4() solenoid shape motion, thereby more efficient and equably annular element 4 is heated.
In addition, Fig. 4 is the plan structure schematic diagram of the water conservancy diversion spiral fin of the heating unit of the annular element of the utility model embodiment bis-, and Fig. 5 is the perspective view of the water conservancy diversion spiral fin of the heating unit of the annular element of the utility model embodiment bis-.Fig. 4 and Fig. 5 show the structure of the water conservancy diversion spiral fin of the present embodiment from different perspectives.
Can be integrally formed in for water conservancy diversion spiral fin 5 on the inwall of annular housing 3, also can, after annular housing 3 machines, the water conservancy diversion spiral fin 5 of manufacturing be separately fixed on the inwall of annular housing 3.
In the present embodiment, in the inside of annular housing 3, between air flow inlet 301 and air stream outlet 302, form two air flow paths that length is identical, the water conservancy diversion spiral fin structure axisymmetricly of two air flow paths, symmetry axis is the straight line at air flow inlet and air stream outlet place.Particularly, as shown in Figure 4, in two air flow paths, the rotation direction of the water conservancy diversion spiral fin 5 of two air flow paths is contrary, and the spiral-line of the water conservancy diversion spiral fin 5 of two air flow paths is along axis symmetry in cavity.
Such symmetrical structure tool has the following advantages: take annular cavity as example, when whole annular cavity is decomposed into two semicircular ring take the diameter at air flow inlet 301 and air stream outlet 302 places as boundary line, the corresponding air flow path of each semicircular ring, if two the spiral-line of the water conservancy diversion spiral fin 5 of air flow path is symmetrical structure, in the time manufacturing two semicircular ring cavitys, can adopt same mould to complete, not need to design two moulds.
Embodiment tri-
On the basis of embodiment bis-, the utility model has also carried out further improvement to the structure of water conservancy diversion spiral fin 5, below this is elaborated.
The moving process of hot gas flow from air flow inlet 301 to air stream outlet 302, temperature can decline, and heated annular element 4 can reduce gradually with hot gas flow heat, there will be the uneven situation of being heated.
It is known according to Newton's law of cooling,
formula (1)
In the present embodiment, for the heat on hot gas flow and annular element 4 surfaces, effective heat release area when A is the Surface Contact of hot gas flow and annular element 4, T is the temperature of hot gas flow, and Tw is the surperficial temperature of annular element 4, and h is surface coefficient of heat transfer (also referred to as surface heat transmission speed).Known by formula (1), A is relatively-stationary value, therefore, and the heat on hot gas flow and annular element 4 surfaces depend on the temperature difference (T-Tw) between the temperature T of hot gas flow and the surperficial temperature T w of annular element 4 and the product of surface heat transmission speed h.Air flow path from air flow inlet 301 to air stream outlet 302, the temperature T of hot gas flow declines gradually, and the temperature difference (T-Tw) diminishes, and thus, causes heat reduce, and then cause the inequality of being heated of annular element 4.To this, the utility model proposes the decline that compensates the temperature T of hot gas flow by improving surface heat transmission speed h, keep thus heat technical scheme.
Particularly, can, by change arbitrary or any two or change this three parameters in the pitch d, pitch angle alpha will, these three parameters of half of thread angle β of water conservancy diversion spiral fin 5 simultaneously, change surface heat transmission speed h.As shown in Figure 6, the partial cutaway schematic of its annular housing that is provided with water conservancy diversion spiral fin that is the utility model embodiment tri-.There is shown the geometric meaning of pitch d in utility model, pitch angle alpha will, these three parameters of half of thread angle β.
By changing these parameters, can change surface coefficient of heat transfer h, the heat causing thereby compensation declines from air flow inlet 301 to the temperature air stream outlet 302 reduce, and then whole annular element 4 is heated evenly, obtain the consistent heat that approaches of " whole story " or " from beginning to end " and whole air flow path.
In the present embodiment, flow type calorifier 1 heated air-flow enter the air flow path of annular housing at air-flow before.Under these circumstances, from air flow inlet 301 to air stream outlet 302, the temperature T of hot gas flow is reduction trend.To this, the present embodiment has carried out the improvement of following three aspects: to water conservancy diversion spiral fin 5, and the improvement of this three aspects: optionally one is implemented, and also any two aspects can be combined to enforcement, also can implement the improvement of these three aspects simultaneously.
1) the pitch d of water conservancy diversion spiral fin 5 is and reduces trend to air stream outlet 302 from air flow inlet 301, is preferably pitch d and reduces gradually.The pitch d of water conservancy diversion spiral fin 5 diminishes and can make hot gas flow speed increase, and forces hot gas flow near annular element 4 surfaces simultaneously, plays the effect that increases the surface coefficient of heat transfer h between hot gas flow and annular element 4.Diminishing of pitch d by water conservancy diversion spiral fin 5 accelerates hot gas flow, the surperficial thermal discharge of annular element 4 is improved, thereby compensate at air flow inlet 301 in the air flow path of air stream outlet 302, because gas flow temperature reduces the reduction to annular element 4 surperficial thermal discharges causing, annular element 4 is heated evenly, and annular element 4 bulk temperatures reach unanimity.That is: becoming in the process of screw pitch, be improved around the hot gas flow flow velocity of annular element 4, the corresponding raising of Reynolds number, nusselt number improves with the raising of Reynolds number, surface coefficient of heat transfer increases by a year-on-year basis with nusselt number, has finally improved the surperficial thermal discharge of annular element 4, i.e. heat .
2) be increase tendency from air flow inlet 301 to air stream outlet 302 from the pitch angle alpha will of water conservancy diversion spiral fin 5, be preferably pitch angle alpha will and increase gradually.The pitch angle alpha will of water conservancy diversion spiral fin 5 increases, and will force hot gas flow close to central axis, near annular element 4 surfaces, also can make hot gas flow speed increase simultaneously, thus, plays the effect that increases the surface coefficient of heat transfer h between hot gas flow and annular element 4.That is: nusselt number is directly proportional to 0.75 power of the cosine function value of pitch angle alpha will, pitch angle alpha will increase will cause nusselt number to increase, surface coefficient of heat transfer h increases by a year-on-year basis with nusselt number, thereby finally improves the surperficial thermal discharge to annular element 4, i.e. heat
3) the half of thread angle β of water conservancy diversion spiral fin 5 is and reduces trend to air stream outlet 302 from air flow inlet 301, is preferably half of thread angle β and reduces gradually.As shown in Figure 6, the half of thread angle of water conservancy diversion spiral fin 5 refers to the angle β that water conservancy diversion spiral fin 5 and the vertical plane of the axis of annular housing form.Half of thread angle reduces, and a collaborative angle is reduced.The reducing of half of thread angle β can force hot gas flow close to central axis equally, near annular element 4 surfaces, plays the effect that increases surface coefficient of heat transfer h, and then improves the surperficial thermal discharge of annular element 4, i.e. heat
Below introduced respectively by pitch d, pitch angle alpha will, these three parameter regulation surface coefficient of heat transfer h of half of thread angle β and then regulated heat principle, below index map 7 is further illustrated by changing surface coefficient of heat transfer h and compensates heat technical scheme.As shown in Figure 7, it is the schematic diagram of the variation relation between the surface coefficient of heat transfer of the utility model embodiment tri-and the temperature of hot gas flow, and in Fig. 7, the semicircle of below represents the movement locus of hot gas flow from air flow inlet to air stream outlet with the curve of arrow.Being located at gas flow temperature is T 0, along with hot gas flow flowing in annular housing, temperature declines gradually, has arrived after air stream outlet, drops to T 1, like this, there is T in air-flow between air flow inlet and air stream outlet 0-T 1the temperature difference, the variation tendency of the temperature on whole air flow path is as Fig. 7 dotted line below line segment, this temperature difference will cause heat reduce.In the time of design water conservancy diversion spiral fin 5, pitch d, pitch angle alpha will, half of thread angle β have been carried out to the design corresponding to temperature variation, even reducing of the pitch gets finer of water conservancy diversion spiral fin 5 and/or the increase of helix angle and/or half of thread angle, thereby indirect regulation surface coefficient of heat transfer h, make on whole air flow path, surface coefficient of heat transfer h is the trend improving gradually, and variation tendency is as the line segment of dotted line top in Fig. 7, be, h at the surface coefficient of heat transfer at air flow inlet place 0, rise to h at air flow outlet 1, between air flow inlet and air stream outlet, there is h 0-h 1difference.Thus, in the heat transfer process of whole air flow path, the reduction of the temperature difference between air-flow and the heating surface of annular element, the surface coefficient of heat transfer being raise gradually compensates, in formula (1), although (T-Tw) decline, the corresponding rising of surface coefficient of heat transfer h, approaches or consistent heat thereby obtain initial and end, pilot process
Thus, by present embodiment, annular element 4 is heated evenly in whole air flow path.Asymmetrical deformation and the warping phenomenon of the annular element 4 producing due to temperature difference heat stress in prior art are avoided.
In addition, the Changing Pattern of the pitch d of water conservancy diversion spiral fin 5 of the present utility model, pitch angle alpha will and half of thread angle β is also not limited to the form of mentioning above, can carry out flexible configuration according to actual heating environment.Be any one or more variation the among pitch d, pitch angle alpha will and the half of thread angle β of water conservancy diversion spiral fin 5, the trend of its variation is to make surface coefficient of heat transfer contrary with the variation tendency of gas flow temperature in air flow path.Like this, control heat by indirect regulation surface coefficient of heat transfer h
Thus, by regulating one or more in these three parameters, control the heating inequality that the temperature variation in air flow path causes.For example, in the time flow type calorifier 1 being set in annular housing, the variation of temperature is not to be simply reduction trend from air flow inlet 301 to air stream outlet 302, but the situation reducing again after existing temperature to raise in stream, for this situation, can make any one or more variations among pitch d, pitch angle alpha will and the half of thread angle β of water conservancy diversion spiral fin 5, and make its variation tendency can compensation current stream in the variation of gas flow temperature.
For the specific design method of pitch d, pitch angle alpha will and the half of thread angle β of water conservancy diversion spiral fin 5, the mode that can set up thermodynamical model by l-G simulation test is simulated and is calculated, and does not repeat them here.
The present embodiment has proposed to arrange water conservancy diversion spiral fin in annular housing, by regulating the pitch d of water conservancy diversion spiral fin 5, one or more adjusting surface coefficient of heat transfer h in these three parameters of pitch angle alpha will and half of thread angle β, and then the technological thought that is subject to thermal conditions of adjusting annular element, such technological thought had not occurred in the technical field of large-scale heating unit in the past, in embodiment of the present utility model, utilize fully heat transfer principle and designed in conjunction with special flow-guiding structure, on whole air flow path, flow state to air-flow reasonably regulates, more accurately heat exchange situation is carried out to regulation and control, make has had significant lifting on the heating uniformity of heat exchanger effectiveness and parts, in this, to there is initiative meaning.
Embodiment tetra-
Above embodiment; heating unit of the present utility model is had been described in detail; in addition, the annular housing of heating unit itself also can be used as one independently parts apply, this annular housing is also the claimed technical scheme of the utility model.
The annular housing of the heating unit of the present embodiment is as shown in Fig. 3, Fig. 4 and Fig. 5, and this annular housing holds heated annular element, is provided with air flow inlet and air stream outlet on the outer wall of this annular housing.
The annular housing of the heating unit of the present embodiment has following technique effect:
1) compared with the furnace chamber of the process furnace of prior art, save the airflow path of the central zone surrounding in annular element, air flow path can be concentrated near annular element, thereby make heat exchange more effective, reduce thermal waste.
2) compared with the process furnace of prior art, reduce the materials consumption of manufacturing furnace chamber body, reduce manufacturing cost.
Further, in annular housing, can be provided with baffle, this baffle makes described air-flow equably along the apparent motion of described annular element.By baffle is set in annular housing, thereby the flow pattern of air-flow is controlled, thus, annular element is heated evenly, and improve heating efficiency.
Preferably, baffle is water conservancy diversion spiral fin.Make to enter hot blast track in annular housing and become the solenoid shape motion around annular element by water conservancy diversion spiral fin is set, thus more efficient and equably annular element is heated.
In view of above embodiment to annular housing with and water conservancy diversion spiral fin be fully described, therefore, the content of all about annular housing in above embodiment, all can be considered about the content of the embodiment of annular housing, does not repeat them here.
By above embodiment, the heating unit of annular element of the present utility model is elaborated.It is to be noted, the heating unit of the annular element of the utility model embodiment and the annular housing of heating unit, can be applied to the heating of all kinds of annular elements, include but not limited to circular ring part, elliptical perimeter parts, rectangular loop parts, trilateral annular element etc., correspondingly, this annular housing also can be made into above-mentioned all kinds of annulars.Preferably, the heating unit of the utility model embodiment is applicable to the heating of large size bearing base part.In addition, the cross section of annular housing is also not limited to circle, can be made into arbitrary shape according to the shape of annular element.
Although represent with reference to preferred embodiment and described the utility model, it should be appreciated by those skilled in the art that in the case of not departing from the spirit and scope of the present utility model that are defined by the claims, can carry out various modifications and conversion to these embodiment.

Claims (22)

1. the heating unit of an annular element, this heating unit heats described annular element by hot gas flow, it comprises flow type calorifier and blower fan, it is characterized in that, this heating unit also comprises the annular housing that holds described annular element, on the outer wall of this annular housing, be provided with air flow inlet and air stream outlet, described flow type calorifier heats described air-flow, described blower fan makes described air-flow enter described air flow inlet, after the air flow path in described annular housing, discharge from described air stream outlet.
2. the heating unit of annular element according to claim 1, is characterized in that, in described annular housing, is provided with baffle, and this baffle makes described air-flow equably along the apparent motion of described annular element.
3. the heating unit of annular element according to claim 2, is characterized in that, described baffle is water conservancy diversion spiral fin.
4. the heating unit of annular element according to claim 3, is characterized in that, described flow type calorifier heated described air-flow before described air-flow enters the air flow path in annular housing.
5. the heating unit of annular element according to claim 4, is characterized in that,
The pitch of described water conservancy diversion spiral fin is and reduces trend to described air stream outlet from described air flow inlet; And/or
The helix angle of described water conservancy diversion spiral fin is increase tendency from described air flow inlet to described air stream outlet; And/or
The half of thread angle of described water conservancy diversion spiral fin is and reduces trend to described air stream outlet from described air flow inlet.
6. the heating unit of annular element according to claim 3, it is characterized in that, any one or more variation among pitch, helix angle and the half of thread angle of described water conservancy diversion spiral fin, the trend of its variation is to make surface coefficient of heat transfer contrary with the variation tendency of gas flow temperature in air flow path.
7. the heating unit of annular element according to claim 3, is characterized in that, described water conservancy diversion spiral fin is integrally formed on the inwall of described annular housing.
8. the heating unit of annular element according to claim 3, it is characterized in that, in described annular housing, between described air flow inlet and air stream outlet, form two air flow paths that length is identical, the water conservancy diversion spiral fin structure axisymmetricly of described two air flow paths, symmetry axis is the straight line at described air flow inlet and air stream outlet place.
9. according to the heating unit of the arbitrary described annular element of claim 1 to 8, it is characterized in that, described annular housing is engaged and is formed by upper annular housing and lower annular housing.
10. the heating unit of annular element according to claim 9, is characterized in that, described upper annular housing is engaged and formed by multiple annular Cavity units, and described lower annular housing is engaged and formed by multiple lower annular housings unit.
11. according to the heating unit of the arbitrary described annular element of claim 1 to 7, it is characterized in that, described air flow inlet and described air stream outlet are arranged on the outer wall of inner side of described annular housing, described flow type calorifier and described blower fan are arranged on the inner side of described annular housing, form airtight airflow circulation passage between the inner chamber of described air flow inlet, described annular housing, described air stream outlet, described blower fan and described flow type calorifier.
The heating unit of 12. annular elements according to claim 11, is characterized in that, in described annular housing, forms two air flow paths that length is identical between described air flow inlet and air stream outlet.
The heating unit of 13. annular elements according to claim 11, is characterized in that, described air-flow is airflow, is provided with air filter at described air flow outlet.
The annular housing of 14. 1 kinds of heating units, is characterized in that, this annular housing holds heated annular element, is provided with air flow inlet and air stream outlet on the outer wall of this annular housing.
The annular housing of 15. heating units according to claim 14, is characterized in that, in described annular housing, is provided with baffle, and this baffle makes described air-flow equably along the apparent motion of described annular element.
The annular housing of 16. heating units according to claim 15, is characterized in that, described baffle is water conservancy diversion spiral fin.
The annular housing of 17. heating units according to claim 16, is characterized in that,
The pitch of described water conservancy diversion spiral fin is and reduces trend to described air stream outlet from described air flow inlet; And/or
The helix angle of described water conservancy diversion spiral fin is increase tendency from described air flow inlet to described air stream outlet; And/or
The half of thread angle of described water conservancy diversion spiral fin is and reduces trend to described air stream outlet from described air flow inlet.
The annular housing of 18. heating units according to claim 17, it is characterized in that, any one or more variation among pitch, helix angle and the half of thread angle of described water conservancy diversion spiral fin, the trend of its variation is to make surface coefficient of heat transfer contrary with the variation tendency of gas flow temperature in air flow path.
The annular housing of 19. heating units according to claim 16, is characterized in that, described water conservancy diversion spiral fin is integrally formed on the inwall of described annular housing.
The annular housing of 20. heating units according to claim 16, it is characterized in that, in described annular housing, between described air flow inlet and air stream outlet, form two air flow paths that length is identical, the water conservancy diversion spiral fin structure axisymmetricly of described two air flow paths, symmetry axis is the straight line at described air flow inlet and air stream outlet place.
21. annular housings according to claim 14 to 20 arbitrary described heating units, is characterized in that, described annular housing is engaged and formed by upper annular housing and lower annular housing.
The annular housing of 22. heating units according to claim 21, is characterized in that, described upper annular housing is engaged and formed by multiple annular Cavity units, and described lower annular housing is engaged and formed by multiple lower annular housings unit.
CN201320880768.3U 2013-12-26 2013-12-26 Heating device for annular component and annular cavity of heating device Withdrawn - After Issue CN203700442U (en)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN103725863A (en) * 2013-12-26 2014-04-16 北京金风科创风电设备有限公司 Heating device of annular part and annular cavity of heating device

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN103725863A (en) * 2013-12-26 2014-04-16 北京金风科创风电设备有限公司 Heating device of annular part and annular cavity of heating device
WO2015096624A1 (en) * 2013-12-26 2015-07-02 北京金风科创风电设备有限公司 Heating device for annular component and annular cavity thereof
CN103725863B (en) * 2013-12-26 2015-12-16 北京金风科创风电设备有限公司 A kind of heating unit of annular element and annular housing thereof
US10378822B2 (en) 2013-12-26 2019-08-13 Beijing Goldwind Science & Creation Windpower Equipment Co., Ltd. Heating device for annular component and annular cavity thereof

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