CN110364062A - Thermionic generation experimental provision including temperature controlled container - Google Patents
Thermionic generation experimental provision including temperature controlled container Download PDFInfo
- Publication number
- CN110364062A CN110364062A CN201910663830.5A CN201910663830A CN110364062A CN 110364062 A CN110364062 A CN 110364062A CN 201910663830 A CN201910663830 A CN 201910663830A CN 110364062 A CN110364062 A CN 110364062A
- Authority
- CN
- China
- Prior art keywords
- component
- experimental provision
- caesium
- thermionic generation
- generation experimental
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Granted
Links
Classifications
-
- G—PHYSICS
- G09—EDUCATION; CRYPTOGRAPHY; DISPLAY; ADVERTISING; SEALS
- G09B—EDUCATIONAL OR DEMONSTRATION APPLIANCES; APPLIANCES FOR TEACHING, OR COMMUNICATING WITH, THE BLIND, DEAF OR MUTE; MODELS; PLANETARIA; GLOBES; MAPS; DIAGRAMS
- G09B23/00—Models for scientific, medical, or mathematical purposes, e.g. full-sized devices for demonstration purposes
- G09B23/06—Models for scientific, medical, or mathematical purposes, e.g. full-sized devices for demonstration purposes for physics
- G09B23/18—Models for scientific, medical, or mathematical purposes, e.g. full-sized devices for demonstration purposes for physics for electricity or magnetism
- G09B23/188—Models for scientific, medical, or mathematical purposes, e.g. full-sized devices for demonstration purposes for physics for electricity or magnetism for motors; for generators; for power supplies; for power distribution
Landscapes
- Engineering & Computer Science (AREA)
- General Physics & Mathematics (AREA)
- Physics & Mathematics (AREA)
- Mathematical Physics (AREA)
- Computational Mathematics (AREA)
- Algebra (AREA)
- Mathematical Analysis (AREA)
- Mathematical Optimization (AREA)
- Power Engineering (AREA)
- Pure & Applied Mathematics (AREA)
- Business, Economics & Management (AREA)
- Educational Administration (AREA)
- Educational Technology (AREA)
- Theoretical Computer Science (AREA)
- Electron Sources, Ion Sources (AREA)
- X-Ray Techniques (AREA)
Abstract
The present invention provides a kind of thermionic generation experimental provision including temperature controlled container, it includes being arranged with being aligned for the emitter component of launching electronics, with emitter component and for receiving the receiving pole component of the electronics emitted by transmitting level assembly and being arranged between emitter component and receiving pole component and formed the electrode connection component in the space for passing through electronics, it further includes temperature controlled container, and at least emitter component and electrode connection component are arranged in temperature controlled container.Thermionic generation experimental provision according to the present invention carries out temperature control to thermionic generation experimental provision by the way that at least emitter component and electrode connection component are arranged in temperature controlled container, and thus, it is possible to the caesium steams in the inner cavity to electrode connection component to carry out pressure control, it is possible thereby to change the power generation characteristics of thermionic generation experimental provision by the pressure for changing caesium steam, be conducive to further investigate relationship between the two.
Description
Technical field
The present invention relates to thermionic generation technical fields, more particularly, to a kind of for thermionic generation system
The thermionic generation experimental provision of characteristic progress experimental study.
Background technique
Thermionic generation is a kind of technology that thermal energy is directly changed into electric energy by way of thermionic emission.By with
The combination of specific heat-supplying mode, thermionic generation can be applied in different occasions, especially combined with nuclear reactor disintegration energy
Manufactured thermionic reactor power supply has unique advantage in space application field, and in the space of Russian TOPAZ series
It is verified in nuclear power system flight test.Thermionic generation experimental provision is that necessity of thermionic generation technological development is set
It is standby.
The principle of thermionic generation is to use to be parallel to each other close refractory metal as electrode pair, wherein emitter quilt
It is heated to 1500 DEG C or more of high temperature and generates thermionic emission, the side of temperature lower (500 DEG C -600 DEG C) is as electronics
Receiving pole.Electron transport pass through electrode before gap when resistance is transported to the generation of the electronics of subsequent transmission.To avoid space electric
The influence of lotus effect, usual way are that caesium steam is filled with into electrode gap, and making the ionization of caesium steam is plasma, to drop
The low potential barrier transported.
Thermionic generation experimental provision belongs to accurate thermoelectricity vacuum device.Influence the principal element packet of thermionic generation
Include: the pressure of electrode material and its caesium steam in temperature, electrode gap width and electrode gap, the change of these parameters is all
It will affect the C-V characteristic of power generator.The basic function of thermionic generation experimental provision be realize different electrode temperatures,
The measurement of VA characteristic curve is carried out under electrode gap width and caesium vapor pressure.In the prior art, thermionic generation experiment dress
The form for the electrode structure set can be divided into flat pole and hollow edged electrode, wherein the processing of the experimental provision of flat pole
It manufactures relatively convenient and is normally used for thermionic generation experimental study.
According to the documentary investigation to the relevant technologies, there are caesiums for the electrode system of existing thermionic generation experimental provision
The temperature control problem of steam.Caesium vapor pressure in electrode gap is controlled by the temperature of caesium tank, from caesium tank to electrode gap
It fills caesium pipeline and is heated to caesium tank temperature degree or more, guarantee that caesium tank temperature degree is in minimum temperature point.It needs filling caesium in the prior art
Heater strip is wound on pipeline, and arranges corresponding temperature-measuring heat couple to monitor temperature.In fact, since experimental provision structure is tight
Gather, be difficult to arrange temperature-measuring heat couple in certain close-connected regions, and in actual conservative operation, will often fill caesium pipeline and
Electrode system is heated to excessively high temperature, this will be unfavorable for the operation steady in a long-term of power generator.
Therefore, it needs a kind of to more accurately control the temperature for filling caesium pipeline and thus between coordination electrode in the prior art
The pressure of caesium steam in gap and the thermionic generation experimental provision of temperature, by temperature and the pressure of control caesium steam so that hair
Electric installation operates steadily in the long term.
Summary of the invention
For related defects present in the above-mentioned problems in the prior art and related existing equipment, the present invention exists
On the basis of the basic demand for meeting the heat of thermionic generation device, electricity and vacuum condition, the solution of drawbacks described above has been comprehensively considered
Certainly scheme, have devised a set of synthetic innovation, it is rigorous easily with the thermion of plate thermion transfer electron system
Generator experimental device.
At least one of in order to solve the above-mentioned technical problem aspect includes temperature control the embodiment provides one kind
The thermionic generation experimental provision of container, the thermionic generation experimental provision include:
Emitter component is used for launching electronics;
Receiving pole component is arranged and for receiving the electronics emitted by transmitting level assembly with being aligned with emitter component;With
And
Electrode connection component is arranged between emitter component and receiving pole component, and forms the sky for passing through electronics
Between,
Wherein, thermionic generation experimental provision further includes temperature controlled container, and at least emitter component and electrode connection component is set
It sets in temperature controlled container.
Thermionic generation experimental provision according to the present invention is by the way that at least emitter component and electrode connection component are arranged
Come to carry out temperature control to thermionic generation experimental provision in temperature controlled container, and thus, it is possible to the inner cavities to electrode connection component
In caesium steam carry out pressure control, it is possible thereby to change thermionic generation experimental provision by the pressure for changing caesium steam
Power generation characteristics, to be furtherd investigate to relationship between the two.
One preferred embodiment of thermionic generation experimental provision according to the present invention, temperature controlled container includes for accommodating
At least the tubular shell of emitter component and electrode connection component and closed end cap is carried out to tubular shell.
In another preferred embodiment of thermionic generation experimental provision according to the present invention, temperature controlled container further includes
Pedestal, wherein tubular shell or end cap are slidably arranged on pedestal.
Another preferred embodiment of thermionic generation experimental provision according to the present invention, on the inner wall of temperature controlled container
It is provided with heating tube or heating coil.
In another preferred embodiment of thermionic generation experimental provision according to the present invention, thermionic generation experiment
Device further includes caesium tank and fills caesium pipeline for what caesium tank was fluidly connected to electrode connection component, fills caesium pipeline at least
It is most of to be arranged in temperature controlled container.
Also a preferred embodiment, the temp controlled vessel of thermionic generation experimental provision according to the present invention are heated to temperature
Degree is higher than the temperature of the caesium steam in caesium tank.
In another preferred embodiment of thermionic generation experimental provision according to the present invention, receiving pole component includes
Receiving terminal unit and the 4th flange of sealing, receiving terminal unit and the 4th flange seal and insulated company are provided for receiving terminal unit
It connects.
An also preferred embodiment for thermionic generation experimental provision according to the present invention, receiving terminal unit include receiving
Extreme plate, the second support tube for supporting receiving pole end plate and the supporting member for supporting the second support tube.
In another preferred embodiment of thermionic generation experimental provision according to the present invention, in the second support tube
It is provided with temperature control component.
Another preferred embodiment of thermionic generation experimental provision according to the present invention, temperature control component include that setting exists
The cooling collar at the center of the second support tube and the electric heating coil being formed in winding on the inner wall of the second support tube.
The problem of present invention is in view of caesium temperature control poor reliability present in existing thermionic generation experimental provision, proposes
The system schema for solving this defect is conducive to establish more accurate, rigorous convenient experimental provision.Specifically, according to
Thermionic generation experimental provision of the invention has the advantages that compared with the existing technology, devises receiving thermionic generation
At least emitter component of experimental provision and the temperature controlled container of electrode connection component, by being heated to temperature controlled container, with reality
Now the temperature of caesium steam is controlled, thus only need to be in the periphery arrangement heating for filling caesium pipeline on a small quantity being exposed to outside temperature controlled container
Silk.The temperature in caesium pipeline is filled come the pressure of the caesium steam in coordination electrode gap by control, and thus, it is possible to caesium vapour pressure
Influence of the power to the power generation performance of thermionic generation experimental provision is studied.
Detailed description of the invention
By the description made for the present invention of below with reference to attached drawing, other objects and advantages of the present invention will be aobvious and easy
See, and can help that complete understanding of the invention will be obtained.
Fig. 1 is the perspective view of the thermionic generation experimental provision according to the present invention including temperature controlled container.
Fig. 2 is the part of the removal temperature controlled container of the thermionic generation experimental provision according to the present invention including temperature controlled container
Cross-sectional view.
Fig. 3 is the section view of the emitter component of the thermionic generation experimental provision according to the present invention including temperature controlled container
Figure.
Fig. 4 is the section view of the receiving pole component of the thermionic generation experimental provision according to the present invention including temperature controlled container
Figure.
Fig. 5 is the part of the electrode connection component of the thermionic generation experimental provision according to the present invention including temperature controlled container
Cross-sectional view.
It should be noted that attached drawing is not necessarily to scale to draw, but only not influence the schematic of reader's understanding
Mode is shown.
Specific embodiment
To make the object, technical solutions and advantages of the present invention clearer, below in conjunction with the attached drawing of the embodiment of the present invention,
Technical solution of the present invention is clearly and completely described.Obviously, described embodiment is an implementation of the invention
Example, instead of all the embodiments.Based on described the embodiment of the present invention, those of ordinary skill in the art are without creating
Property labour under the premise of every other embodiment obtained, shall fall within the protection scope of the present invention.
Unless otherwise defined, the technical term or scientific term that the present invention uses should be tool in fields of the present invention
The ordinary meaning for thering is the personage of general technical ability to be understood.
As depicted in figs. 1 and 2, the thermionic generation experimental provision 10 according to the present invention including temperature controlled container is shown respectively
Perspective view and partial sectional view.Thermionic generation experimental provision 10 includes the emitter component 12 and hair for launching electronics
Emitter-base bandgap grading component 12 is aligned and the receiving pole component 14 for receiving the electronics emitted by transmitter module 12 and setting are emitting
Between pole component 12 and receiving pole component 14 and formed pass through electronics space electrode connection component 16.Hereinafter with reference to
Attached drawing is respectively illustrated each component part of thermionic generation experimental provision 10 according to the present invention.
Firstly, being said referring to attached drawing 3 to the emitter component 12 of thermionic generation experimental provision 10 according to the present invention
It is bright.Emitter component 12 includes unit heater 122 and transmitting end unit 124, wherein unit heater 122 is electric heater
Unit comprising electric heater 1222, the heater support 1224 for supporting electric heater 1222 are used to be heater support
1224 provide and support and be that electric heater 1222 provides the first flange 1226 of power cathode and for for electric heater
1222 provide the second flange component 1228 of positive pole.Electric heater 1222 can use high-temperature electric heat material, such as can be with
For tungsten, it is of course also possible to use other high-temperature electric heat materials, are not specifically limited herein.Electric heater 1222 can pass through weldering
It the connection types such as connecing and is connected to heater support 1224, heater support 1224 is then fixedly connected to first flange 1226,
This can also be attached by welding.First flange 1226 and the sealing of second flange component 1228 and insulated company
It connects, for example isolating pad can be set between first flange 1226 and second flange component 1228, which can rise
To the effect of sealing, moreover it is possible to play the role of insulation, further, it is also possible to first flange 1226 and second flange component 1228 it
Between sealing ring is set, for improving leakproofness between the two.First flange 1226 can be connected with the cathode of power supply, for for
Electric heater 1222 provides power cathode, and second flange component 1228 can connect to the anode of power supply, for being electric heater
1222 provide positive pole.
Second flange component 1228 for providing positive pole for electric heater 1222 includes second flange 12282, sets
It sets in the ceramic sleeve 12284 in the centre bore of second flange 12282 and the electrode stem being arranged in ceramic sleeve 12284
12286, electrode stem 12286 can connect to the anode of external power supply, to be electric heater by electrode stem 12286
1222 provide positive pole.
Emitting end unit 124 includes emitter end plate 1242, the first support tube for supporting emitter end plate 1242
1244, it is set in the heat shielding pipe 1246 of the periphery of the first support tube 1244 and for supporting above-mentioned first support tube, 1244 and
The third flange 1248 of heat shielding pipe 1246.Emitter end plate 1242 is as thermionic generation experimental provision according to the present invention
Emitter, for being made of metal material, for example can be made of tungsten to receiving pole launching electronics.Further, since needs pair
The temperature of emitter end plate 1242 is monitored, and accommodates associated temperature detection in being internally provided with for emitter end plate 1242 thus
The monitoring holes of device are herein through-hole.Emitter end plate 1242 can be soldered on the end of the first support tube 1244, such as can
It is welded in a manner of through electron beam welding, the first support tube 1244 can also be made of molybdenum material, and electric heater 1222 is set
It sets in the inside of the first support tube 1244.It can be selected herein according to emitter end plate 1242 and the material of the first support tube 1244
Suitable welding manner is selected, such as the first bearing is made for the emitter end plate 1242 made of tungsten as described above and by molybdenum
For pipe 1244, the welding of tungsten and molybdenum is realized by the way of electron beam welding, herein used welding condition are as follows: electricity
Stream is 18.5mA, weld interval 15s.
The other end of first support tube 1244 is fixedly connected to third flange 1248, herein first support tube 1244
The other end is connected to third flange 1248 by welding manner.Heat shielding pipe 1246 can also be made of molybdenum material, and its
Third flange 1248 can also be soldered to.As shown in Fig. 3, the end plane of heat shielding pipe 1246 and emitter end plate 1242
Outer surface is substantially flush or the outer surface of emitter end plate 1242 is slightly prominent.It can be set in this heat shielding pipe 1246
It for double-layer structure, that is, include two heat shielding pipes of collocated, thus, it is possible to be the first support tube 1244 and its internal
Electric heater 1222 provides more excellent heat-proof quality.
Since third flange 1248 is generally made of stainless steel (herein referring to for S.S.304 type stainless steel, similarly hereinafter), therefore
In order to improve the weldability between the first support tube 1244 and heat shielding pipe 1246 and third flange 1248, in third flange
Setting can cut down transition piece 1250 at 1248 position welded with the first support tube 1244 and heat shielding pipe 1246, can cut down transition piece
1250 may be adapted to be welded with various metals or nonmetallic materials, for example it can be niobium zirconium alloy, by using can cut down
Crossing part 1250 the first support tube 1244 and heat shielding pipe 1246 being made to be respectively welded at can cut down on transition piece 1250, and can cut down
Transition piece 1250 can be then welded on third flange 1248.In addition, in order to which that improves third flange 1248 closes on heat shielding pipe
The leakproofness of 1246 side, can be arranged on the side of heat shielding pipe 1246 accommodate sealing ring annular groove, so as to its
He provides being absolutely sealed for the connection surface when component is tightly connected.Pumping can also be set on the periphery of third flange 1248
Interface 1252 can carry out vacuumize process by inside of the suction interface 1252 to emitter component 12, so that electricity adds
The components such as hot device 1222, which are under vacuum state, to be operated.
In order to ensure the inside of emitter component 12 leakproofness and unit heater 122 and transmitting end unit 124 it
Between dielectric relationship, that is, the dielectric relationship between first flange 1226 and third flange 1248 needs to make unit heater
122 carry out insulated enclosure connection with transmitting end unit 124, i.e., insulation is established between first flange 1226 and third flange 1248
It is tightly connected.By the first metal to ceramic sealing part 126, (metal to ceramic sealing part as described herein can be that can cut down-Al herein2O3-
Can cut down, similarly hereinafter) first flange 1226 and third flange 1248 are welded to connect, Lai Shixian unit heater 122 and transmitting
The insulated enclosure of end unit 124 connects.First metal to ceramic sealing part 126 can be set into including the first ceramic member 1262 and
Component 1266 can be cut down by being arranged in the first of the two sides of the first ceramic member 1262 and can cutting down component 1264 and second, and first can cut down component
1264 side can weld together with third flange 1248, and first other side that can cut down component 1264 can be with the first pottery
Porcelain piece 1262 welds together, and correspondingly, the second side that can cut down component 1266 can weld together with first flange 1226,
And second other side that can cut down component 1266 can weld together with the first ceramic member 1262, it is possible thereby to form emitter group
The inner space of the sealing of part 12.First can cut down component 1264 and second can cut down component 1266 can for kovar alloy, such as
Niobium zirconium alloy, the first ceramic member 1262 can be made of alumina material.Not only by using the first metal to ceramic sealing part 126
Both dielectric relationship can be provided, and can be realized by welding for first flange 1226 and third flange 1248
Between sealed connection.Hereby it is achieved that the sealing and insulation between unit heater 122 and transmitting end unit 124 connect.
Welding between first metal to ceramic sealing part 126 and first flange 1226 and third flange 1248 can use pricker
Weldering mode is realized.Further, in order to avoid substep welding causes the thermal stress breakage gas leakage of the first ceramic member 1262, first
Metal to ceramic sealing part 126 is with the first flange 1226 being made of stainless steel and third flange 1248 for being located at its two sides using whole
The mode of body soldering is welded, for example, carry out simultaneously first flange 1226 and second can cut down between component 1266, second can cut down
Between component 1266 and the first ceramic member 1262, the first ceramic member 1262 and first can be cut down between component 1264 and first can cut down
Welding between component 1264 and third flange 1248, overall, and by unit heater 122 and transmitting terminal
Unit 124 is welded with the first metal to ceramic sealing part 126 simultaneously, that is, carries out the weld job of 4 weld seams simultaneously, by
The thermal stress generated between each welding assembly when this can greatly reduce weld job prevents from generating due to thermal stress
Part distortion, to prevent the rupture of weld seam.Here, needing to mention to before can cutting down component and ceramic member progress vacuum brazing
It is preceding to by Al2O3Manufactured ceramic member carries out metalized, and brazing solder uses AgCu28.4 weld seams are carried out at the same time
It is integral braze-welded when, need to grip workpiece, welding condition are as follows: brazing temperature is 885 DEG C, and soaking time is
15min。
Electric heater 1222 is arranged in the first support tube 1244, and electric heater 1222 is connected by electrode stem 12286
External DC power supply, makes the tungsten heating sheet of electric heater 1222 be increased to 1000 DEG C or so of high temperature under the action of direct current
Thermionic emission is generated, negative pressure is applied to tungsten heating sheet on this basis, so that electronics accelerates bombardment to arrive emitter end plate 1242
On, thus the emission temperature needed for obtaining, and electronics is launched by emitter end plate 1242.
The receiving pole component 14 of 4 pairs of thermionic generation experimental provisions 10 according to the present invention is said referring to the drawings
It is bright.Receiving pole component 14 includes receiving terminal unit 142 and provides the 4th flange 144 of sealing for receiving terminal unit 142.Receiving end
Unit 142 is including receiving pole end plate 1422, the second support tube 1424 for supporting receiving pole end plate 1422 and for supporting
The supporting member 1426 of above-mentioned second support tube 1424.Receiving pole end plate 1422 can have or phase identical as emitter end plate 1242
As structure, receiving pole of the receiving pole end plate 1422 as thermionic generation experimental provision 10 according to the present invention, for receiving
The electronics for carrying out self-electrode, is made of metal material, for example can be made of molybdenum.Due to needing to the extreme plate 1422 of reception
Temperature is monitored, thus receiving pole end plate 1422 be internally provided with accommodate associated temperature detection device monitoring holes, than
Such as through-hole as shown in the figure.Receiving pole end plate 1422 can be soldered on the end of the second support tube 1424, for example can pass through
The mode of electron beam welding is welded, and the second support tube 1424 can also be made of molybdenum material, the second support tube 1424 it is another
End is fixedly connected to supporting member 1426, here, supporting member 1426 can be made by that can cut down material, for example is niobium zirconium alloy.
Second support tube 1424 can be made of molybdenum, it is possible thereby to be welded direct on supporting member 1426.In 1422 He of receiving pole end plate
For second support tube 1424 by situation made of molybdenum material, the two can be integrally formed, such as can be by cylindricality molybdenum
Internal material is removed in material, and receiving pole end plate 1422 and the second support tube 1424 are formed in a manner of forming blind hole.
Further, the 4th flange 144 is used to provide sealing for receiving pole component 14, is connected to when by receiving pole component 14
When electrode connection component 16, the 4th flange 144 can be tightly sealed with electric grade connection component 14.In order to ensure supporting member 1426
Insulation and sealing relationship between the 4th flange 144, that is, in order to realize the 4th flange 144 and receiving terminal unit 142 it
Between insulated enclosure connection, need supporting member 1426 and the progress insulated enclosure connection of the 4th flange 144, herein can be by the
Two metal to ceramic sealing parts 146 are welded to connect supporting member 1426 and the 4th flange 144.Second metal to ceramic sealing part
146, which can be set into the third including the second ceramic member 1462 and the two sides that the second ceramic member 1462 is arranged in, can cut down component
1464 and the 4th can cut down component 1466, and the side that third can cut down component 1464 can weld together with supporting member 1426, and the
Three other sides that can cut down component 1464 can weld together with the second ceramic member 1462, and correspondingly, the 4th can cut down component 1466
Side can weld together with the 4th flange 144, and the 4th other side that can cut down component 1466 can be with the second ceramic member
1462 weld together, it is possible thereby to formed between supporting member 1426 and the 4th flange 144 (namely the 4th flange 144 and reception
Between end unit 142) insulated enclosure connection.Third can cut down component 1464 and the 4th can cut down component 1466 can be by kovar alloy
It is made, for example is niobium zirconium alloy, the second ceramic member 1462 can be made of alumina material.It is sealed by using the second cermet
Fitting 146 can provide the sealed connection with good insulating performance for supporting member 1426 and the 4th flange 144.Since conjunction can be cut down
Fitting has a good welds performance with metal and nonmetallic materials, therefore can be realized between different metal by the way that material can be cut down,
Metal with it is nonmetallic between and it is nonmetallic with it is nonmetallic between be fixedly connected.
Welding between second metal to ceramic sealing part 146 and supporting member 1426 and the 4th flange 144 can use vacuum
Brazing mode is realized.Further, in order to avoid substep welding causes the thermal stress of the second ceramic member 1462 damaged, the second gold medal
Belong to crunch seal part 146 be located at its two sides supporting member 1426 and the 4th flange 144 using overall vacuum be brazed by the way of into
Row welding, for example (as receiving terminal unit 142 and the 4th method can be cut down between component 1464 by carrying out supporting member 1426 and third simultaneously
Orchid 144 between), third can be cut down between component 1464 and the second ceramic member 1462, the second ceramic member 1462 and the 4th can cut down component
Between 1466 and the 4th can cut down Welding between component 1466 and the 4th flange 1466, that is, carry out 4 welderings simultaneously
The weld job of seam, it is possible thereby to the thermal stress generated between each welding assembly when greatly reducing weld job, prevent by
In the part distortion that thermal stress generates, to prevent the rupture of weld seam and associated welds component.
In order to be provided with temperature control component 148 in the second support tube 1424 to the extreme progress of plate 1422 temperature control is received,
The temperature control component 148 includes that the cooling collar 1482 at the center of the second support tube 1424 is arranged in and is formed in second with winding
Electric heating coil 1484 on the inner wall of support tube 1424, it is possible thereby to which it is right to open cooling collar 1482 when needing cooling down
Second support tube 1424 and receiving pole end plate 1422 are cooled down, and when needing heating heating, then pass through electric heating coil
1484 pair of second support tube 1424 and receiving pole end plate 1422 heat, and herein can be DC heating.Cooling collar 1482
For two root canal roads of collocated, two pipelines can be connected in the terminal fluid connecting with receiving pole end plate 1422, thus
Coolant (for example can be inert gas) circulation canal that formed inner tube flows into, outer tube flows out, or form outer tube and flow into, is interior
The coolant circulation passage of pipe outflow.Cooling collar 1482 can connect to external coolant circulating system, thus to cooling
Agent is recycled, to obtain good cooling effect.
The excessive phenomenon in heating region caused by the reinforcement transmitting effect of emitter edge in order to prevent, in receiving pole
Protective case 1428 is arranged in the end of component 14, and protective case 1428 is nested at the end of receiving pole end plate 1422 and the second support tube 1424
In portion.Protective case 1428 can be made of aluminium oxide, be made into cylindrical shape, the protective case 1428 of the cylindrical shape with receiving pole end plate
1422 ends matched are formed with inner chamfer (as shown in Figure 4), thus with 1422 phase of receiving pole end plate with outer chamfer
Match.It is possible thereby to absorb the electronics of the outside of the outer rim for being incident on receiving pole end plate 1422 or outer rim by protective case 1428, and
The excessive phenomenon of electronics is not will form.Protective case 1428 can be locked on the second bearing by the circlip 1429 for the side that sets within it
On the outer surface of pipe 1424.The forming region of plasma can be limited in the positive area of electrode by protective case 1428
On, thereby ensure that the accuracy for receiving electric current.
Fig. 5 shows the partial sectional view of the electrode connection component 16 of thermionic generation experimental provision 10 according to the present invention.
Electrode connection component 16 provides the connection space between emitter component 12 and receiving pole component 14, is emitted by emitter component 12
Electronics pass through and the connection space and received by receiving pole component 14.In the sky that the electronics provided by electrode connection component 16 passes through
Between in be full of caesium steam, caesium steam makes the electron ionization plasma passed through, to reduce in Electronic Transport Processes
Potential barrier.The electrode connection component 16 is including emitter connecting pipe 162, receiving pole connecting pipe 164 and fills caesium pipeline
166, wherein emitter connecting pipe 162 and receiving pole connecting pipe 164 be coaxially disposed, i.e. emitter connecting pipe 162
Axis and the axis of receiving pole connecting pipe 164 are in axial direction aligned or are overlapped, so that being mounted on emitter connecting tube
Emitter end plate 1242 in road 162 being capable of central place with the receiving pole end plate 1422 being mounted in receiving pole connecting pipe 164
Alignment, so that the electronics launched from emitter end plate 1242 can all be transported to receiving pole end plate 1422 as much as possible
On.Herein advantageously, it fills caesium pipeline 166 to be vertically arranged with emitter connecting pipe 162 and receiving pole connecting pipe 164, i.e.,
Three can be arranged at " fourth " font.It can be arranged on filling caesium pipeline 166 and fill caesium connecting flange 1662, be used for and come from caesium tank
Pipeline link together, the caesium in caesium tank is thus filled into the intracavitary of electrode connection component 16.
Further, emitter connecting pipe 162 and receiving pole connecting pipe 164 respectively include a mounting flange,
That is emitter connecting pipe 162 includes the first mounting flange 1622, receiving pole connecting pipe 1.64 includes the second fixation
Orchid 1.642, the first mounting flange 1622 can with the third flange 1248 of emitter component 12 it is relatively fixed link together,
And opposing seal between the two, the second mounting flange 1642 then can be relatively solid with the 4th flange 144 of receiving pole component 14
Surely it links together, and also opposing seal between the two.In emitter connecting pipe 162 and receiving pole connecting pipe 164
Between link position at be formed with and can observe relative position between emitter end plate 1242 and receiving pole end plate 1422 and close
The observation window 168 of system.
In order to mitigate the thermal stress of thermionic generation experimental provision 10 according to the present invention and prevent from being caused by thermal stress
Part distortion, elastic connecting element can be set in emitter connecting pipe 162 and/or receiving pole connecting pipe 164, than
For example bellows a, it is preferable that elastic joint part is set in emitter connecting pipe 162 or receiving pole connecting pipe 164
Part.In the embodiment as shown in fig.5, elastic connecting element 170 is only set in receiving pole connecting pipe 164, due to
There is elastic connecting element 170 scalability therefore to cope with by emitter component 12, receiving pole component 14 and/or electrode
The thermal stress of connection component 16 and the deformation generated.
Further, it is also possible to which spare connecting flange 1664 is arranged on filling caesium pipeline 166, caesium connecting flange 1662 can filled
In the case where inconvenient to use, caesium tank is connected using spare connecting flange 1664.It in emitter connecting pipe 162 and can also connect
The spare filling channel 172 of setting at the position that pole connecting pipe 164 connects is received, it can be by spare filling channel 172 to electrode
The intracavitary of connection component 16 is filled with gas needed for others.
As shown in Fig. 2, thermionic generation experimental provision 10 according to the present invention further includes for adjusting emitter component 12
The distance regulating mechanism 18 of the distance between receiving pole component 14 can adjust electrode connection group by distance regulating mechanism 18
The distance between first mounting flange 1622 and the second mounting flange 1642 of part 16, can be real by elastic connecting element 170
Ensure that the spacing under the conditions of excellent sealing is adjusted now.Distance regulating mechanism 18 is designed for driving the first mounting flange 1622
Or second mounting flange 1642 move, to change the distance between emitter end plate 1242 and receiving pole end plate 1422, thus
It can be special to the distance between emitter end plate 1242 and receiving pole end plate 1422 and the power generation of thermionic generation experimental provision 10
Relationship between property is studied.
Here, by being added in thermionic generation experimental provision 10 between emitter component 12 and receiving pole component 14
The distance distance regulating mechanism 18 that is adjusted and measures, can measure and adjust emitter end plate 1242 and receiving pole end plate
Spacing between 1422, to change the C-V characteristic of thermionic generation experimental provision 10, and based on this to electrode spacing and heat
Correlation between the power generation characteristics of ion generator experimental device carries out experimental study.
Referring to attached drawing 2 to the specific structure of the distance regulating mechanism 18 of thermionic generation experimental provision 10 according to the present invention
It is illustrated.Distance regulating mechanism 18 includes and the relatively fixed driver plate that connect of ground of the 4th flange 144 of receiving pole component 14
182, it is drivingly connect with driver plate 182 and the drive rod 184 and driving drive rod 184 for driving driver plate 182 to move is transported
Dynamic driving mechanism 186.Driving mechanism 186 can be micrometer driving mechanism, can be in the movement of driving drive rod 184
It highly precisely can also measure or control simultaneously the move distance of drive rod 184.Here, driving mechanism 186 can be made and passed
Lever 184 is threadedly engaged, and makes 186 axial restraint of driving mechanism and circumferential rotatable, thus in the driving machine that rotates in a circumferential direction
When structure 186, drive rod 184 is axially moved forward and backward, and thus driver plate 182 is driven to move, and driver plate 182 passes through connection
Bar 188 drives the movement of the 4th flange 144, so that receiving pole connecting tube of the receiving pole component 14 together with electrode connection component 16
One side section of the separate emitter component 12 positioned at elastic connecting element 170 in road 164 moves together, to change emitter
The distance between component 12 and receiving pole component 14.It is of course also possible to driving mechanism 186 is arranged to fixed structure, with driving
The drive rod 184 that mechanism 186 is threadedly engaged can make rotating motion with respect to driving mechanism 186, correspondingly, drive rod 184 and biography
Between movable plate 182 can relative rotation, but the two is in axial direction relatively fixed, drives drive rod 184 to rotate phase as a result,
Driver plate 182 can be then transferred to for the axial movement of driving mechanism 186, driver plate 182 is then connect by the drive of connecting rod 188
Pole component 12 is received to move.Here, distance regulating mechanism 18 can also be arranged to drive being located at for thermionic generation experimental provision 10
The component of the other side of elastic connecting element 170, such as the emitter of driving emitter component 12 and electrode connection component 16
Connecting pipe 162, the thus also spacing between adjustable emitter component 12 and receiving pole component 14.It is, of course, also possible to will
Elastic connecting element 170 is arranged in emitter connecting pipe 162, meanwhile, driving also can be set into distance regulating mechanism 18
Any one of emitter component 12 and receiving pole component 14.
It is possible thereby to change or set the emitter end plate 1242 of emitter component 12 by distance regulating mechanism 18 and connect
The spacing between the receiving pole end plate 1422 of pole component 14 is received, thus to study the spacing and thermionic generation experimental provision 10
The basic guarantee that relationship between power generation characteristics provides.
In order to solve the Temperature Controlling of caesium steam, at least emitter component 12 and electrode connection component 16 are arranged in temperature control
In container 20, naturally it is also possible to 14 1 pieces of receiving pole component are arranged in temperature controlled container 20, temperature controlled container 20 is mainly used for controlling
The temperature positioned at the intracavitary caesium steam for filling caesium pipeline and electrode connection component 16 flowed out from caesium tank is made, to ensure to fill caesium pipeline
The temperature of interior caesium steam is higher than the temperature of the caesium steam in caesium tank.The temperature of caesium tank and the temperature for filling caesium pipeline are below caesium
Boiling point, thus the pressure of caesium steam by be located at temp controlled vessel 20 outside caesium tank temperature (minimum temperature in caesium system) into
Row controls to adjust.By the temperature in control caesium tank come the pressure of the intracavitary caesium steam of coordination electrode connection component 16, thus
Influence to the pressure of caesium steam to the power generation performance of thermionic generation experimental provision 10 is studied.It can be in temperature controlled container 20
Inner wall on arrange heating tube or heating coil, the vacuum for making entire thermionic generation experimental provision 10 maintain 400 DEG C or so
In environment, this design method can substitute the scheme that heater strip is wound on the periphery for all filling caesium pipeline, it is only necessary in exposure
Heater strip is arranged in filling on caesium pipeline except temperature controlled container 20, thus avoids the appearance of caesium cold spot.
Temperature controlled container 20 may include at least emitter component 12 and electricity for accommodating thermionic generation experimental provision 10
The tubular shell 202 of pole connection component 16 and closed end cap 204 is carried out to tubular shell 202, as an alternative,
The receiving pole component 14 of thermionic generation experimental provision 10 also can be set in tubular shell 202, tubular shell 202 and end cap
204 can be separately positioned on pedestal 206, and any one of tubular shell 202 and end cap 204 can be slidably arranged in pedestal
It on 206, for example can be slidably arranged in by sliding rail on pedestal 206, thus, it is possible to open temperature controlled container 20 so as to being located at
Thermionic generation experimental provision 10 therein is checked and is operated.Correspondingly, can temperature controlled container 20 external setting with
The relevant operating member of thermionic generation experimental provision 10 or connecting component, for example be arranged on the side wall of tubular shell 202
Observation panel 208 corresponding with the observation window 168 of electrode connection component 16, be arranged on the end wall of tubular shell 202 with electricity
The corresponding external electrode flange 210 of pole piece column 12286.Of course, it is possible to which being provided on tubular shell 202 and end cap 204 makes
Thermionic generation experimental provision 10 and external port or the interface for carrying out relevant connection or operation, herein can according to actual needs into
Row arrangement.
As a preferred embodiment of the invention, which further includes caesium tank and by caesium
What tank was fluidly connected to electrode connection component 16 fills caesium pipeline, wherein at least most of setting for filling caesium pipeline is being controlled
In warm container 20.It is arranged in temperature controlled container 20 here, caesium pipeline will can all be filled, i.e., only caesium tank is located at temperature controlled container 20
Outside, or for the convenience of connection, the small part of only connection caesium tank fills the outside that caesium pipeline is located at temperature controlled container 20,
So temperature control can be carried out to the most of of caesium pipeline is filled, thus to the caesium steam in the inner cavity of electrode connection component 16 into
The control of row pressure, and thus the relationship between the pressure to caesium steam and the power generation characteristics of thermionic generation experimental provision 10 carries out
Research.
Thermionic generation experimental provision 10 according to the present invention has the characteristics that modularized design, mainly includes emitter
The advantages of three component, receiving pole component and electrode connection component modules, this modularized design, is conducive to modules
Maintenance and replacement.Electrode connection component can be used as a relatively-stationary module, can be right when needing replacing electrode material
Emitter component or receiving pole component quickly carry out integral replacing.For example some module occurs to destroy or damage in operation
It ruins, the module of destruction can individually be dismantled, it, then can be with without the module that goes wrong so that it is repaired or replaced
It keeps original state and can continue to use, to accelerate the maintenance process of equipment, shorten maintenance cycle.
Thermionic generation experimental provision according to the present invention by the metal parts to metal to ceramic sealing part and two sides into
Row integral braze-welded welding, solve ceramics in welding process and subsequent use process due to thermal stress and damaged cracking is asked
Topic, it is ensured that metal to ceramic sealing part is with better insulation and sealing performance and has longer service life.Devise set
The ceramic protective sleeve in the end of receiving pole component is set, thus, it is possible to heating region is constrained in the positive area of electrode
In, to prevent the excessive of plasma.The present invention is also driven emitter component and is connect by driving mechanism and drive rod
It receives pole component and relative motion occurs, so that the spacing between emitter component and receiving pole component is adjusted, further by having
The micrometer driving mechanism of micrometer carrys out the spacing between measuring electrode, also by flexible connector, such as bellows, to adjust
Internode away from while realize electrode connection component inner cavity sealing, it is possible thereby to by distance regulating mechanism come to spacing and heat
The relationship of the power generation characteristics of ion generator experimental device is studied.The present invention further devises at least receiving thermionic generation
The emitter component of experimental provision and the temperature controlled container of electrode connection component, by being heated to temperature controlled container, with realization pair
The temperature of caesium steam controls, without (need to only be exposed to temperature controlled container in the periphery arrangement heater strip for all filling caesium pipeline
Except the periphery for filling caesium pipeline on heater strip is set), it is thus more accurate to the control of caesium temperature and caesium pressure.
For the embodiment of the present invention, it is also necessary to explanation, in the absence of conflict, the embodiment of the present invention and reality
Applying the feature in example can be combined with each other to obtain new embodiment.
More than, only a specific embodiment of the invention, but scope of protection of the present invention is not limited thereto, and it is of the invention
Protection scope should be subject to the protection scope in claims.
Claims (10)
1. a kind of thermionic generation experimental provision including temperature controlled container, comprising:
Emitter component is used for launching electronics;
Receiving pole component is arranged and for receiving by the electricity of the transmitting level assembly transmitting with being aligned with the emitter component
Son;And
Electrode connection component is arranged between the emitter component and the receiving pole component, and formation makes the electronics
The space passed through,
It is characterized in that, the thermionic generation experimental provision further includes temperature controlled container, at least described emitter component and described
Electrode connection component is arranged in the temperature controlled container.
2. thermionic generation experimental provision according to claim 1, which is characterized in that the temperature controlled container includes for holding
Receive at least described emitter component and the electrode connection component tubular shell and the tubular shell is carried out closed
End cap.
3. thermionic generation experimental provision according to claim 2, which is characterized in that the temperature controlled container further includes bottom
Seat, wherein the tubular shell or the end cap are slidably arranged on the pedestal.
4. thermionic generation experimental provision according to any one of claim 1-3, which is characterized in that hold in the temperature control
Heating tube or heating coil are provided on the inner wall of device.
5. thermionic generation experimental provision according to claim 1, which is characterized in that the thermionic generation experimental provision
Further include caesium tank and fills caesium pipeline for what the caesium tank was fluidly connected to the electrode connection component, it is described to fill caesium pipe
At least most of setting in road is in the temperature controlled container.
6. thermionic generation experimental provision according to claim 5, which is characterized in that the temp controlled vessel is heated to temperature
Degree is higher than the temperature of the caesium steam in the caesium tank.
7. thermionic generation experimental provision according to claim 1, which is characterized in that the receiving pole component includes receiving
End unit and provide the 4th flange of sealing for the receiving terminal unit, the receiving terminal unit and the 4th flange seal and
Insulated connection.
8. thermionic generation experimental provision according to claim 7, which is characterized in that the receiving terminal unit includes receiving
Extreme plate, the second support tube for supporting the receiving pole end plate and the supporting member for supporting second support tube.
9. thermionic generation experimental provision according to claim 8, which is characterized in that be arranged in second support tube
There is temperature control component.
10. thermionic generation experimental provision according to claim 9, which is characterized in that the temperature control component includes setting
The electricity on inner wall for being formed in second support tube in the cooling collar at the center of second support tube and winding adds
Heat coil.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201910663830.5A CN110364062B (en) | 2019-07-22 | 2019-07-22 | Thermal ion power generation experimental device comprising temperature control container |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201910663830.5A CN110364062B (en) | 2019-07-22 | 2019-07-22 | Thermal ion power generation experimental device comprising temperature control container |
Publications (2)
Publication Number | Publication Date |
---|---|
CN110364062A true CN110364062A (en) | 2019-10-22 |
CN110364062B CN110364062B (en) | 2021-08-20 |
Family
ID=68220570
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN201910663830.5A Active CN110364062B (en) | 2019-07-22 | 2019-07-22 | Thermal ion power generation experimental device comprising temperature control container |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN110364062B (en) |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN110927775A (en) * | 2019-12-11 | 2020-03-27 | 中国原子能科学研究院 | Modularized electric heating simulation heat source for ETG |
Citations (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN201270483Y (en) * | 2008-08-06 | 2009-07-08 | 中国科学院理化技术研究所 | Fluid metal cooling focusing type solar thermoionic power generation apparatus |
CN102695924A (en) * | 2009-11-16 | 2012-09-26 | 苏纳珀有限公司 | Energy storage systems |
CN202586808U (en) * | 2012-05-22 | 2012-12-05 | 张维国 | Novel high-efficiency thermionic power supply |
CN103427709A (en) * | 2012-05-22 | 2013-12-04 | 张维国 | Novel high-efficiency thermionic power supply |
CN203660926U (en) * | 2013-12-26 | 2014-06-18 | 张维国 | Thermionic power supply power generation unit |
JP2016025208A (en) * | 2014-07-18 | 2016-02-08 | 株式会社デンソー | Thermal transfer device, temperature controller, internal combustion engine, internal combustion engine exhaust system and melting furnace |
CN109818530A (en) * | 2019-01-22 | 2019-05-28 | 孟宪忠 | Energy-saving thermal electric generator-the heat engine of Vacuum Heat electronics |
-
2019
- 2019-07-22 CN CN201910663830.5A patent/CN110364062B/en active Active
Patent Citations (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN201270483Y (en) * | 2008-08-06 | 2009-07-08 | 中国科学院理化技术研究所 | Fluid metal cooling focusing type solar thermoionic power generation apparatus |
CN102695924A (en) * | 2009-11-16 | 2012-09-26 | 苏纳珀有限公司 | Energy storage systems |
CN202586808U (en) * | 2012-05-22 | 2012-12-05 | 张维国 | Novel high-efficiency thermionic power supply |
CN103427709A (en) * | 2012-05-22 | 2013-12-04 | 张维国 | Novel high-efficiency thermionic power supply |
CN203660926U (en) * | 2013-12-26 | 2014-06-18 | 张维国 | Thermionic power supply power generation unit |
JP2016025208A (en) * | 2014-07-18 | 2016-02-08 | 株式会社デンソー | Thermal transfer device, temperature controller, internal combustion engine, internal combustion engine exhaust system and melting furnace |
CN109818530A (en) * | 2019-01-22 | 2019-05-28 | 孟宪忠 | Energy-saving thermal electric generator-the heat engine of Vacuum Heat electronics |
Non-Patent Citations (1)
Title |
---|
王远,苏山河,郭君诚,陈金灿: "真空热离子发电器的性能优化和参数设计", 《工程热物理学报》 * |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN110927775A (en) * | 2019-12-11 | 2020-03-27 | 中国原子能科学研究院 | Modularized electric heating simulation heat source for ETG |
Also Published As
Publication number | Publication date |
---|---|
CN110364062B (en) | 2021-08-20 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
JP6411211B2 (en) | Anode with linear main extension direction | |
CN102639945B (en) | Absorber tube | |
CN110417296A (en) | Thermionic generation experimental provision with protective case | |
US10801753B2 (en) | Method and device for introducing protective gas into a receiver tube | |
Wells et al. | Mechanical design and fabrication of the VHF-gun, the Berkeley normal-conducting continuous-wave high-brightness electron source | |
CN110364062A (en) | Thermionic generation experimental provision including temperature controlled container | |
CN109945979A (en) | A kind of infrared detector module Dewar shell mechanism for Cryogenic Optical System | |
CN110310553A (en) | The adjustable thermionic generation experimental provision of electrode gap | |
CN110390863A (en) | Using the thermionic generation experimental provision of electrode assembly integral solder technique | |
CN104801844B (en) | A kind of tantalum and the electro-beam welding method of tungsten metal thin-wall circumferential weld | |
JP2008064548A (en) | Simulated fuel rod for nuclear reactor | |
JP2007149601A (en) | X-ray tube and the x-ray inspection device using it | |
JP2012004060A (en) | X-ray source and adjusting apparatus and method for the same | |
CN107764436B (en) | Tungsten-rhenium thermocouple calibration device | |
JP2023067807A (en) | Fluid-cooled reflective x-ray source | |
CN107068216B (en) | X-ray flaw detector for welding line of high-temperature gas cooled reactor heat exchange tube | |
CN107210186B (en) | For using single-ended infrared emitter that infra-red radiation is injected into the irradiation devices in vacuum processing chamber | |
CN115046988A (en) | Melt immersion probe based on LIBS technology, online detection device and detection method | |
CN106944697A (en) | A kind of welding method of four wings octagon radio frequency four polar field accelerator cavity | |
CN101745735B (en) | Electric heating plug welding technique for engine | |
CN212936273U (en) | Accelerating tube whole tube working stress absorbing device | |
CN114381714B (en) | Miniature in-situ temperature measurement high-temperature atomic molecule evaporation and emission device | |
CN114783634B (en) | Heating assembly for simulating accident condition of pressurized water reactor nuclear power station | |
US7201514B2 (en) | Fluid connection assembly for x-ray device | |
CN214309761U (en) | Steam sampling tube mechanism for high-temperature and high-pressure steam pipeline of thermal power plant |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
PB01 | Publication | ||
PB01 | Publication | ||
SE01 | Entry into force of request for substantive examination | ||
SE01 | Entry into force of request for substantive examination | ||
GR01 | Patent grant | ||
GR01 | Patent grant |