CN102794242B - For the spray water flow quantity regulating device of accumulated ice sleet pilot system - Google Patents
For the spray water flow quantity regulating device of accumulated ice sleet pilot system Download PDFInfo
- Publication number
- CN102794242B CN102794242B CN201210285127.3A CN201210285127A CN102794242B CN 102794242 B CN102794242 B CN 102794242B CN 201210285127 A CN201210285127 A CN 201210285127A CN 102794242 B CN102794242 B CN 102794242B
- Authority
- CN
- China
- Prior art keywords
- shower water
- water supply
- charge
- shower
- accumulated ice
- 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.)
- Expired - Fee Related
Links
Landscapes
- Testing Resistance To Weather, Investigating Materials By Mechanical Methods (AREA)
Abstract
The invention provides a kind of spray water flow quantity regulating device for accumulated ice sleet pilot system, this device comprises: supply water one point linker more, is connected to the water inlet of the shower water supply pipe of accumulated ice sleet pilot system; All-in-One water supply linker, is connected to the delivery port of the shower water supply pipe of accumulated ice sleet pilot system; Multiple shower water supply is in charge of, and is connected in water supply linker more than a point in parallel and between All-in-One water supply linker; Multiple shower water switch-dividing, each shower water switch-dividing is arranged on each shower water supply and is in charge of, control the opening/closing that each shower water supply is in charge of respectively, wherein, the shower water introduced from the water inlet of shower water supply pipe is divided to multiple shower water supply is in charge of by water supply linker more than a point, multiple shower water supply be in charge of in shower water be flowed to All-in-One water supply linker, then multiple nozzles of accumulated ice sleet pilot system are directed to by the delivery port of shower water supply pipe, to spray given the test agent.
Description
Technical field
The invention belongs to accumulated ice sleet environmental test field, relate to a kind of spray water flow quantity regulating device for accumulated ice sleet pilot system.
Background technology
Sleet is also glaze, and sleet freezes and can break electric wire after forming accumulated ice on the object of temperature lower than zero degree, and cause power supply and communication disruption, serious sleet even can press the house that collapses, and breaks trees, and freeze to death crops and vegetables.In addition, the loss that sleet disaster causes communications and transportation is also very serious, when aircraft flies in the cloud layer having super-cooling waterdrop, and the wing of aircraft, screw meeting accumulated ice, thus affect aircraft air power performance and cause accident.Usually, for the product be exposed under accumulated ice/sleet environment, accumulated ice/sleet may cause product that corresponding physics and chemistry effect occurs, and affects reliability and the work newly energy of product, even causes product break down or damage.
Therefore, need the development carrying out accumulated ice sleet environmental test system (equipment), to carry out accumulated ice/sleet environmental test in advance to the product be exposed under accumulated ice/sleet environment, thus improve the reliability of product.In addition, a kind of spray water flow quantity regulating device is also needed accurately to regulate shower water flow, to carry out accurate accumulated ice/sleet environmental test to product.
Summary of the invention
An aspect of of the present present invention is to provide a kind of spray water flow quantity regulating device for accumulated ice sleet pilot system, this spray water flow quantity regulating device can accurately regulate shower water flow, to carry out accurate accumulated ice/sleet environmental test to product, to improve targetedly product, thus improve the reliability of product.
According to an aspect of the present invention, provide a kind of spray water flow quantity regulating device for accumulated ice sleet pilot system, described spray water flow quantity regulating device comprises: supply water one point linker more, is connected to the water inlet of the shower water supply pipe of accumulated ice sleet pilot system; All-in-One water supply linker, is connected to the delivery port of the shower water supply pipe of accumulated ice sleet pilot system; Multiple shower water supply is in charge of, and is connected in water supply linker more than a point in parallel and between All-in-One water supply linker; Multiple shower water switch-dividing, each shower water switch-dividing is arranged on each shower water supply and is in charge of, control the opening/closing that each shower water supply is in charge of respectively, wherein, the shower water introduced from the water inlet of shower water supply pipe is divided to multiple shower water supply is in charge of by water supply linker more than a point, multiple shower water supply be in charge of in shower water be flowed to All-in-One water supply linker, then multiple nozzles of accumulated ice sleet pilot system are directed to by the delivery port of shower water supply pipe, to spray given the test agent.
The cross-sectional area that described multiple shower water supply is in charge of can increase successively.
The ratio of the cross-sectional area that any two adjacent shower water supplies are in charge of can be 1/2.
The controller of accumulated ice sleet pilot system can according to the shower water flow of the shower water supply pipe measured, each shower water switch-dividing is controlled separately, corresponding shower water supply is in charge of and is opened or closed, and makes the shower water flow that the shower water flow of the delivery port of shower water supply pipe reaches predetermined.
Described multiple shower water switch-dividing can be jettron.
The quantity that shower water supply is in charge of can be 4-8.
The quantity that shower water supply is in charge of is preferably 5.
Accompanying drawing explanation
In conjunction with the drawings, from the description of the following examples, the present invention these and/or other side and advantage will become clear, and are easier to understand, wherein:
Fig. 1 is the structured flowchart of the accumulated ice sleet pilot system illustrated according to the embodiment of the present invention;
Fig. 2 illustrates the shower water flow of accumulated ice sleet pilot system according to the embodiment of the present invention and the control block diagram of gas supply flow;
Fig. 3 is the detailed structure view of the spray water flow quantity regulating device illustrated according to the embodiment of the present invention;
Fig. 4 is the schematic diagram of the comparative result that the shower water flow regulating effect according to prior art and the shower water flow regulating effect according to the embodiment of the present invention are shown;
Fig. 5 is the detailed structure view of the gas supply flow adjusting device illustrated according to the embodiment of the present invention.
Detailed description of the invention
Below, embodiments of the invention are described in detail with reference to accompanying drawing.
Fig. 1 is the structured flowchart of the accumulated ice sleet pilot system illustrated according to the embodiment of the present invention.Fig. 2 illustrates the shower water flow of accumulated ice sleet pilot system according to the embodiment of the present invention and the control block diagram of gas supply flow.
See figures.1.and.2, accumulated ice sleet pilot system comprises casing 1, and the bottom of casing 1 is provided with lifting turntable 2, and lifting turntable 2 can place given the test agent 3, and can oscilaltion and/or rotation, to change height and the angle of given the test agent 3.
The top of casing 1 is provided with storage tank 4, in storage tank 4, stores the shower water (pre-cold water) needed for the test of accumulated ice sleet.Storage tank 4 utilizes the natural-drop of shower water to produce shower water pressure, therefore can supply shower water.
Shower water supply pipe 5 is connected to storage tank 4.Shower water in storage tank 4 is fed to multiple nozzle 6 by shower water supply pipe 5.Multiple nozzle 6 can be arranged in top and the surrounding of given the test agent 3.Multiple nozzle 6 is sprayed water to given the test agent 3, thus carries out the test of accumulated ice sleet.
Shower water supply pipe 5 is provided with spray water flow quantity regulating device 7 and spray water flow gauge 8.Spray water flow gauge 8 detects the shower water flow of shower water supply pipe 5 in real time, and spray water flow quantity regulating device 7 regulates the shower water flow of shower water supply pipe 5.The shower water flow that controller 18 is measured according to spray water flow gauge 8, the shower water flow controlling spray water flow quantity regulating device 7 pairs of shower water supply pipes 5 regulates, and makes the shower water flow that the shower water flow of shower water supply pipe 5 reaches predetermined.
Shower water supply pipe 5 can be provided with shower water master switch 9, and shower water master switch 9 opens or closes shower water supply pipe 5 according to the control of controller 18.
Accumulated ice sleet pilot system also can comprise the water temperature regulation device 10 be arranged in casing 1, can be provided with cooling-water temperature sensor (not shown) in storage tank 4, and cooling-water temperature sensor measures the temperature of the shower water in storage tank 4.The temperature of the shower water that controller 18 is measured according to cooling-water temperature sensor, controls water temperature regulation device 10 and regulates the temperature of the shower water in storage tank 4 to reach predetermined water temperature.For the test of accumulated ice sleet, the predetermined water temperature of shower water is preferably 3 DEG C to 5 DEG C, is beneficial to accelerate to form accumulated ice/sleet on given the test agent 3.
Accumulated ice sleet pilot system also can comprise the automatic water-replenishing device 11 (such as water pump) being connected to storage tank 4, can be provided with level sensor (not shown) in storage tank 4, and level sensor measures the water level of the shower water in storage tank 4.The water level of the shower water that controller 18 is measured according to level sensor, controls automatic water-replenishing device 11 pairs of storage tank 4 automatic water supplements.Automatic water-replenishing device 11 by outside watering to storage tank 4 automatic water supplement.
Cooling rapidly to enable the shower water on given the test agent 3, solidifying icing, also need to regulate box interior temperature.Therefore, accumulated ice sleet pilot system also comprises the box interior temperature adjusting device (not shown) be arranged in casing 1 and the temperature sensor being arranged on box house, temperature sensor measurement box interior temperature, controller 18, according to temperature sensor measurement box interior temperature, controls casing internal thermostat and regulates box interior temperature to reach predetermined box interior temperature.For the test of accumulated ice sleet, box interior temperature is preferably-6 DEG C to-10 DEG C, is beneficial to accelerate to form accumulated ice/sleet on given the test agent 3.
Due to when carrying out accumulated ice/sleet test, nozzle 6 sprays given the test agent 3 in environment below 0 DEG C, if therefore do not carry out safeguard procedures, nozzle 6 will freeze after a period of operation gradually, and final nozzle freezes, and causes normally spraying.And in actual use, in order to reach better freezing effects, preferably, need the water of spray to be atomized, can uniform fold to the surface of given the test agent 3, reach quick freezing effects.
Therefore, accumulated ice sleet pilot system also can comprise high-pressure air source 12, and high-pressure air source 12 produces the gas of predetermined pressure.
Air supply pipe 13 is connected to high-pressure air source 12.The gas that high-pressure air source 12 produces is fed to multiple nozzle 6 by air supply pipe 13.The shower water supply of gas and shower water supply pipe 5 that air supply pipe 13 is supplied each nozzle 6 understand with, the water that nozzle 6 is sprayed is atomized, and the water uniform fold of atomization is to the surface of given the test agent 3.
Air supply pipe 13 is provided with gas supply flow adjusting device 14 and gas supply flow meter 15.Gas supply flow meter 15 detects the gas supply flow of air supply pipe 13 in real time, the gas supply flow that controller 18 is measured according to gas supply flow meter 15, the gas supply flow controlling gas supply flow adjusting device 14 pairs of air supply pipes 13 regulates, and makes the gas supply flow that the gas supply flow of air supply pipe 13 reaches predetermined.
Air supply pipe 13 can be provided with air feed master switch 16, and air feed master switch 16 opens or closes air supply pipe 13 according to the control of controller 18.
Accumulated ice sleet pilot system also can comprise the gas temperature adjusting device 17 be arranged in casing 1, can be provided with gas temperature sensor (not shown) in the exit of high-pressure air source 12, gas temperature sensor measures the gas temperature in the exit of high-pressure air source 12.The gas temperature that controller 18 is measured according to cooling-water temperature sensor, controls the gas temperature that gas temperature adjusting device 17 regulates the gas temperature in the exit of high-pressure air source 12 to reach predetermined.For the test of accumulated ice sleet, the gas temperature in the exit of high-pressure air source 12 is preferably 10 DEG C to 12 DEG C.
In order to prevent nozzle 6 from freezing, the gases at high pressure that high-pressure air source 12 produces control through excess temperature, can guarantee that nozzle 6 is in more than 0 DEG C to prevent localized ice build when flowing through nozzle 6.Nozzle 6 passes through gases at high pressure high velocity stream through water jet front, the effect of water jet insulation can be reached, siphon principle can be utilized water sucking-off again and utilize high-speed gas to flow and rapidly shower water (temperature controls at 3 DEG C to about 5 DEG C) is atomized, arrive the surface of given the test agent 3 at spray before, cooled rapidly by the low temperature environment of-6 DEG C to-10 DEG C in casing, reach the effect of subcooled water, can freeze by rapid solidification after making it fall the surface of given the test agent 3, be convenient to carry out the test of accumulated ice sleet.
Mutually restrict with atomized water is icing because nozzle is antifreeze, if that is, gas temperature is high, gas flow rate (gas supply flow) large, then nozzle good freezing protection effect, but cause atomization water temperature high, the sprinkling landing time is short, and atomization freezing effects is poor; Otherwise, if gas temperature is low, gas flow rate (gas supply flow) is little, be then atomized freezing effects good and nozzle antifreezing effect is poor.For this reason, by theory calculate and limited number of time experiment, obtain the fit correlation between gas temperature, gas flow rate (gas supply flow) and water discharge rate (shower water flow), thus realize the Optimization Balancing of nozzle antifreezing effect and atomization freezing effects.Therefore, in the present invention, according to water discharge rate (shower water flow) adjustments of gas temperature and the whiff pressure (gas supply flow) automatically of setting, the automatic adjustment of whole controlled quentity controlled variable can be realized.
Below the adjustment of spray water flow amount and gas supply flow are regulated and be described in detail.
Fig. 3 is the detailed structure view of the spray water flow quantity regulating device 7 illustrated according to the embodiment of the present invention.
Referring to figs. 1 through Fig. 3, spray water flow quantity regulating device 7 comprises water supply linker 71 more than a point, 72-1 to 72-N is in charge of in multiple shower water supply, multiple shower water switch-dividing 73-1 to 73-N and All-in-One water supply linker 74.N is natural number.
Water supply linker 71 more than one point is connected to the water inlet 51 of shower water supply pipe 5, All-in-One water supply linker 74 is connected to the delivery port 52 of shower water supply pipe 5, and multiple shower water supply is in charge of 72-1 to 72-N and is connected in water supply linker 71 more than a point in parallel and between All-in-One water supply linker 74.The shower water introduced from the water inlet 51 of shower water supply pipe 5 is divided to multiple shower water supply by water supply linker 71 more than a point and is in charge of 72-1 to 72-N.Multiple shower water switch-dividing 73-1 to 73-N is separately positioned on multiple shower water supply and is in charge of 72-1 to 72-N above (namely, each shower water supply be in charge of be provided with a shower water switch-dividing), multiple shower water supply can be opened or closed respectively and be in charge of 72-1 to 72-N.Multiple shower water supply shower water be in charge of in 72-1 to 72-N is flowed to All-in-One water supply linker 74, is then directed to multiple nozzle 6 to spray given the test agent 3 by the delivery port 52 of shower water supply pipe 5.
The cross-sectional area that 72-1 to 72-N is in charge of in multiple shower water supply increases successively.Preferably, the ratio of cross-sectional area that any two adjacent shower water supplies are in charge of is 1/2.Correspondingly, the ratio of internal diameter that any two adjacent shower water supplies are in charge of is
the ratio of the cross-sectional area be in charge of due to any two adjacent shower water supplies is 1/2, and the ratio of shower water flow that therefore any two adjacent shower water supplies are in charge of also is 1/2.
The shower water flow that controller 18 can be measured according to spray water flow gauge 8, each shower water switch-dividing is controlled separately, corresponding shower water supply is in charge of and is opened or closed, and makes the shower water flow that the shower water flow of the delivery port 52 of shower water supply pipe 5 reaches predetermined.
Under control of the controller 18, each shower water switch-dividing can open or close separately shower water supply and be in charge of, and the ratio of the shower water flow that any two adjacent shower water supplies are in charge of is 1/2, and therefore, the shower water total flow that N number of shower water supply is in charge of has 2
nplant syntagmatic (similar with binary number), 2 of the flow of shower water can be realized
nlevel regulates, and degree of regulation is that shower water total flow when all opening is in charge of in N number of shower water supply
therefore, the accurate adjustment of shower water flow can be realized.
Can determine the size of N as required, such as, N can be 4 to 8, Fig. 3 situations showing that N is 5.When N is 5, the shower water total flow that 5 shower water supplies are in charge of has 2
5(that is, 32) plant syntagmatic, and can realize 32 grades of adjustments of the flow of shower water, degree of regulation is that 1/32 of shower water total flow when all opening is in charge of in N number of shower water supply.
Shower water switch-dividing 73-1 to 73-N can be jettron.Jettron can open or close corresponding shower water supply under control of the controller 18 fast and be in charge of, and compared with traditional rotary switch, jettron response speed is very fast, is convenient to the shower water flow of the delivery port 52 of quick adjustment shower water supply pipe 5.
Fig. 4 is the schematic diagram of the comparative result that the shower water flow regulating effect according to prior art and the shower water flow regulating effect according to the embodiment of the present invention are shown.
Traditional shower water flow control mode utilizes storage tank self water storage volume change to compare with spray time to calculate average shower water flow, utilizes storage tank pressure itself to control the mean value of water spray.But, instantaneous value due to shower water flow is subject to the impact of storage tank hydraulic pressure, the instantaneous value of shower water flow changes along with the change of storage tank self water yield, and therefore the instantaneous value of shower water flow and the relation of time are curves fluctuated, see (a) in Fig. 4.
In the present invention, spray water flow gauge 8 measures shower water flow in real time, and controller 18, according to the shower water flow measured, controls separately each shower water switch-dividing, according to
precision regulate shower water flow, the fluctuation of the shower water flow instantaneous value caused due to the shower water pressure oscillation in storage tank can be balanced, finally realize the stability contorting of shower water flow.With reference to (b) in Fig. 4, the fluctuation of the shower water flow instantaneous value realized in the present invention is significantly less than the shower water flow instantaneous value of traditional shower water flow control mode realization.
Fig. 5 is the detailed structure view of the gas supply flow adjusting device 14 illustrated according to the embodiment of the present invention.The structure of gas supply flow adjusting device 14 and the similar of spray water flow quantity regulating device 7.
Particularly, with reference to Fig. 1, Fig. 2 and Fig. 4, gas supply flow adjusting device 14 comprises air feed linker 141 more than a point, 142-1 to 142-M is in charge of by multiple air feed, multiple air feed switch-dividing 143-1 to 143-M and All-in-One air feed linker 144.M is natural number.
Air feed linker 141 more than one point is connected to the air inlet 131 of air supply pipe 13, All-in-One air feed linker 144 is connected to the gas outlet 132 of air supply pipe 13, and multiple air feed is in charge of 142-1 to 142-M and is connected in air feed linker 141 more than a point in parallel and between All-in-One air feed linker 144.The gas introduced from the air inlet 131 of air supply pipe 13 is divided to multiple air feed by air feed linker 141 more than a point and is in charge of 142-1 to 142-M.Multiple air feed switch-dividing 143-1 to 143-M is separately positioned on multiple air feed and is in charge of 142-1 to 142-M (that is, each air feed be in charge of be provided with an air feed switch-dividing), can open or close multiple air feed respectively and be in charge of 142-1 to 142-M.Multiple air feed gas be in charge of in 142-1 to 142-M is flowed to All-in-One air feed linker 144, then multiple nozzle 6 is directed to by the gas outlet 132 of air supply pipe 13, described gas be fed to nozzle 6 shower water can and, the water that nozzle 6 is sprayed is atomized, the water uniform fold of atomization to the surface of given the test agent 3, to carry out the test of accumulated ice sleet.
The cross-sectional area that 142-1 to 142-M is in charge of by multiple air feed increases successively.Preferably, the ratio of cross-sectional area that any two adjacent air feed are in charge of is 1/2.Correspondingly, the ratio of internal diameter that any two adjacent air feed are in charge of is
the ratio of the cross-sectional area be in charge of due to any two adjacent air feed is 1/2, and the ratio of gas supply flow that therefore any two adjacent air feed are in charge of also is 1/2.
The gas supply flow that controller 18 can be measured according to gas supply flow meter 15, control separately each air feed switch-dividing, corresponding air feed is in charge of and is opened or closed, and makes the gas supply flow of the gas outlet 132 of air supply pipe 13 reach predetermined gas supply flow.
Under control of the controller 18, each air feed switch-dividing can open or close separately air feed and be in charge of, and the ratio of gas supply flow that any two adjacent air feed are in charge of is 1/2, and therefore, the air feed total flow that M air feed is in charge of has 2
mplant syntagmatic (similar with binary number), 2 of gas supply flow can be realized
mlevel regulates, and degree of regulation is that air feed total flow when all opening is in charge of by M air feed
therefore, the accurate adjustment of gas supply flow can be realized.
Can determine the size of M as required, such as, M can be 4 to 8, Fig. 5 situations showing that M is 5.When M is 5, the air feed total flow that 5 air feed are in charge of has 2
5(that is, 32) plant syntagmatic, and can realize 32 grades of adjustments of gas supply flow, degree of regulation is that 1/32 of air feed total flow when all opening is in charge of by M air feed.
Air feed switch-dividing 143-1 to 143-M can be jettron.Jettron can open or close corresponding air feed under control of the controller 18 fast and be in charge of, and compared with traditional rotary switch, jettron response speed is very fast, is convenient to the gas supply flow of the gas outlet 132 of quick adjustment air supply pipe 13.
M can equal N, that is, the quantity that the quantity that air feed is in charge of can be in charge of with shower water supply is equal, and the quantity of air feed switch-dividing can be equal with the quantity of shower water switch-dividing.But the present invention is not limited thereto, M also can be not equal to N.
As mentioned above, controller 18 can set described predetermined gas supply flow according to the shower water flow (described predetermined shower water flow) of setting, and the gas supply flow of air supply pipe 13 can be adjusted precisely to described predetermined gas supply flow by controller 18.
Accumulated ice sleet pilot system also can comprise heater (not shown).Heater can be arranged in the base plate of casing 1, to bottom plate heating, prevents the atomized water trickled down on the base plate of casing 1 from freezing.The outside that can be discharged to casing 1 by the water of heating devices heat on base plate.
Accumulated ice sleet pilot system according to the present invention accurately can control the shower water flow and the gas supply flow that are supplied to nozzle, make shower water by gases at high pressure atomization and evenly spray on the surface of given the test agent, realize the Optimization Balancing of nozzle antifreezing effect and atomization freezing effects, be beneficial to carry out stablizing, accumulated ice/sleet test accurately.
Accumulated ice/sleet the test of certain hour section (such as several hours) can be carried out to tested products according to accumulated ice sleet pilot system of the present invention, can determine that can product tolerate the environment of accumulated ice/sleet, or can work under the environment of accumulated ice/sleet, thus can improve targetedly product.
Although the present invention is described in detail with reference to its exemplary embodiment and shows, but will be understood by those skilled in the art that, when not departing from the spirit and scope of the present invention be defined by the claims, the various changes of form and details can be carried out to it.
Claims (4)
1., for a spray water flow quantity regulating device for accumulated ice sleet pilot system, comprising:
Supply water one point linker more, is connected to the water inlet of the shower water supply pipe of accumulated ice sleet pilot system;
All-in-One water supply linker, is connected to the delivery port of the shower water supply pipe of accumulated ice sleet pilot system;
Multiple shower water supply is in charge of, and is connected in water supply linker more than a point in parallel and between All-in-One water supply linker;
Multiple shower water switch-dividing, each shower water switch-dividing is arranged on each shower water supply and is in charge of, and controls the opening/closing that each shower water supply is in charge of respectively,
Wherein, the shower water introduced from the water inlet of shower water supply pipe is divided to multiple shower water supply is in charge of by water supply linker more than a point, multiple shower water supply be in charge of in shower water be flowed to All-in-One water supply linker, then multiple nozzles of accumulated ice sleet pilot system are directed to by the delivery port of shower water supply pipe, to spray given the test agent
Wherein, the cross-sectional area that described multiple shower water supply is in charge of increases successively, and the ratio of the cross-sectional area that any two adjacent shower water supplies are in charge of is 1/2,
Wherein, the controller of accumulated ice sleet pilot system is according to the shower water flow of the shower water supply pipe measured, each shower water switch-dividing is controlled separately, corresponding shower water supply is in charge of and is opened or closed, and makes the shower water flow that the shower water flow of the delivery port of shower water supply pipe reaches predetermined.
2. spray water flow quantity regulating device according to claim 1, wherein, described multiple shower water switch-dividing is jettron.
3. spray water flow quantity regulating device according to claim 1, wherein, the quantity that shower water supply is in charge of is 4-8.
4. spray water flow quantity regulating device according to claim 3, wherein, the quantity that shower water supply is in charge of is 5.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201210285127.3A CN102794242B (en) | 2012-08-10 | 2012-08-10 | For the spray water flow quantity regulating device of accumulated ice sleet pilot system |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201210285127.3A CN102794242B (en) | 2012-08-10 | 2012-08-10 | For the spray water flow quantity regulating device of accumulated ice sleet pilot system |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| CN102794242A CN102794242A (en) | 2012-11-28 |
| CN102794242B true CN102794242B (en) | 2015-08-05 |
Family
ID=47193692
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN201210285127.3A Expired - Fee Related CN102794242B (en) | 2012-08-10 | 2012-08-10 | For the spray water flow quantity regulating device of accumulated ice sleet pilot system |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN102794242B (en) |
Families Citing this family (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN105676901B (en) * | 2016-03-16 | 2019-05-31 | 中国直升机设计研究所 | A kind of method of aqueous vapor pressure in quick adjusting cloud control system |
| CN112082787B (en) * | 2020-07-20 | 2022-09-06 | 中航工程集成设备有限公司 | Movable environmental test device |
Citations (6)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| DE3928130A1 (en) * | 1989-08-25 | 1991-02-28 | Max Prof Dr Rer Nat Dr Setzer | Weathering test for concrete or stone - by measuring combined effect of alternating dew and frost and watery soln. by determination of material loss after capillary action |
| CN2144635Y (en) * | 1992-12-30 | 1993-10-27 | 冶金工业部重庆钢铁设计研究院 | Positive-pressure conveying article multi-stage automatic control speed regulating gas supply device |
| CN2886428Y (en) * | 2006-04-18 | 2007-04-04 | 广东美的电器股份有限公司 | Water amount regulator of heat pump water heater |
| CN201527280U (en) * | 2009-11-12 | 2010-07-14 | 河南索凌电气有限公司 | Device for testing ice covering of a line |
| CN201955246U (en) * | 2010-12-01 | 2011-08-31 | 西安大昱光电科技有限公司 | Freezing rain test box |
| CN202254564U (en) * | 2011-08-02 | 2012-05-30 | 山东信合节能服务有限责任公司 | Cooling water treatment device |
-
2012
- 2012-08-10 CN CN201210285127.3A patent/CN102794242B/en not_active Expired - Fee Related
Patent Citations (6)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| DE3928130A1 (en) * | 1989-08-25 | 1991-02-28 | Max Prof Dr Rer Nat Dr Setzer | Weathering test for concrete or stone - by measuring combined effect of alternating dew and frost and watery soln. by determination of material loss after capillary action |
| CN2144635Y (en) * | 1992-12-30 | 1993-10-27 | 冶金工业部重庆钢铁设计研究院 | Positive-pressure conveying article multi-stage automatic control speed regulating gas supply device |
| CN2886428Y (en) * | 2006-04-18 | 2007-04-04 | 广东美的电器股份有限公司 | Water amount regulator of heat pump water heater |
| CN201527280U (en) * | 2009-11-12 | 2010-07-14 | 河南索凌电气有限公司 | Device for testing ice covering of a line |
| CN201955246U (en) * | 2010-12-01 | 2011-08-31 | 西安大昱光电科技有限公司 | Freezing rain test box |
| CN202254564U (en) * | 2011-08-02 | 2012-05-30 | 山东信合节能服务有限责任公司 | Cooling water treatment device |
Also Published As
| Publication number | Publication date |
|---|---|
| CN102794242A (en) | 2012-11-28 |
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| CN102798590B (en) | Icing/freezing rain test system | |
| CN102914416B (en) | Direct-cooling freezing wind tunnel realization method and direct-cooling freezing wind tunnel realization system | |
| CN101608576B (en) | Skid mounted equipment structure for power augmentation system | |
| CN102814249B (en) | For the gas supply flow adjusting device of accumulated ice sleet pilot system | |
| CN104833909A (en) | Artificial simulated climate chamber test device capable of forming multiple icing types | |
| CN104741155A (en) | Weather manual simulation room with icing wind tunnel | |
| CN102794242B (en) | For the spray water flow quantity regulating device of accumulated ice sleet pilot system | |
| CN103471804A (en) | Method and device for water-mist uniformity control | |
| CN102200334B (en) | Water spray humidification control method for clean room and humidification control system | |
| CN107885258A (en) | A kind of cooling wind-tunnel temprature control method based on magnetic valve combination | |
| CN204620012U (en) | A kind of weather manual simulation room with icing tunnel | |
| KR20080060029A (en) | Nozzle device and icing test simulation equipment having the same | |
| CN105044290A (en) | Device for anti-freezing performance testing of anti-freezing coating of wind generating set blade | |
| CN204649915U (en) | A kind of manual simulation climate room test unit that can form multiple icing type | |
| CN201637435U (en) | Ice coating test environment simulation device of long insulator string | |
| CN104807493B (en) | Based on the pressure controlled phjytotron of aqueous vapor multiple icing type forming method | |
| CN208198837U (en) | Hydrophobicity of Composite Insulator automatic measure grading system water injector based on unmanned plane | |
| CN205102477U (en) | Glacial system ice system of experimental usefulness of engine | |
| RU2451919C1 (en) | Icing condition stimulator used in aircraft turbine engine bench tests in heat chambers with piping attached | |
| RU166944U1 (en) | CENTRIFUGAL DECOMPOSITION DEVICE FOR BLADES OF A WIND POWER INSTALLATION | |
| CN113028695B (en) | Water supply and air supply control system of vehicle-mounted snow making machine and vehicle-mounted snow making machine adopting same | |
| CN106583078A (en) | Air source system of ice fog spraying facility | |
| Herman | Goodrich icing wind tunnel overview, improvements and capabilities | |
| CN204564055U (en) | A kind of melt granulation device | |
| CN110589026B (en) | Ground test device of closed-loop aircraft electric anti-icing system |
Legal Events
| Date | Code | Title | Description |
|---|---|---|---|
| C06 | Publication | ||
| PB01 | Publication | ||
| C10 | Entry into substantive examination | ||
| SE01 | Entry into force of request for substantive examination | ||
| C14 | Grant of patent or utility model | ||
| GR01 | Patent grant | ||
| CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20150805 Termination date: 20180810 |
|
| CF01 | Termination of patent right due to non-payment of annual fee |