Windshield durability testing device
1. A windshield durability testing apparatus comprising: a test chamber (11), a holding device (13) for holding a windscreen, and a control system (12) connected to the test chamber (11);
the test chamber (11) comprises: a first working chamber (111) and a second working chamber (112);
the clamping device (13) is located between the first working chamber (111) and the second working chamber (112).
2. The windshield durability test device according to claim 1, wherein the test chamber (11) comprises: the refrigerator comprises a hollow main body (11a), and a first door (11b) and a second door (11c) which are arranged at two opposite ends of the hollow main body (11 a);
the clamping device (13) is located in the hollow main body (11a), and the clamping device (13), the hollow main body (11a) and the first door (11b) enclose the first working chamber (111), and the clamping device (13), the hollow main body (11a) and the second door (11c) enclose the second working chamber (112).
3. The windscreen endurance testing device according to claim 1 or 2, wherein the control system (12) is connected to the first working chamber (111) and to the second working chamber (112), respectively;
the control system (12) is used for controlling the first working chamber (111) to be in a negative pressure environment and the second working chamber (112) to be in a normal pressure environment, and the control system (12) is used for respectively controlling the temperature and the humidity of the first working chamber (111) and the second working chamber (112).
4. The windshield durability test device according to claim 3, wherein the hollow main body (11a) is provided with a sealing structure at a position where it is closed with the first door (11b) and the second door (11c), respectively;
the edges of the first door (11b) and the second door (11c) are provided with defrosting devices, and/or the positions of the hollow main body (11a) which are respectively contacted with the edges of the first door (11b) and the second door (11c) are provided with defrosting devices.
5. The windshield durability test device according to claim 4, wherein the hollow body (11a) is provided with a lighting device and a fan at positions corresponding to the first working chamber (111) and the second working chamber (112), respectively;
the first box door (11b) and the second box door (11c) are respectively provided with at least one transparent observation window.
6. The windshield endurance testing device of claim 5, with the control system (12) comprising: the cabinet body, set up in internal humidity control unit (121), negative pressure control unit (122), temperature control unit (123) of cabinet, set up respectively in first studio (111) with data acquisition sensor (124) in second studio (112), temperature impact unit (125), set up in radiator fan (126) and controller (127) on the cabinet body.
7. The windshield durability test device according to claim 6, wherein the humidity control unit (121) comprises: a humidifier (1211) and a water tank (1212);
the negative pressure control unit (122) includes: a vacuum pump (1221);
the temperature control unit (123) includes: a compressor (1231), an oil separator (1232), a condenser (1233), an expansion vessel (1234), a plate heat exchanger (1235), and a heater;
the data acquisition sensor (124) comprises: a temperature sensor (1241), a humidity sensor (1242) and a pressure sensor;
the temperature impact unit (125) comprises: a water pump, a nozzle (1251) and an axial flow fan (1252).
8. Windscreen durability testing device according to claim 1 or 2, characterized in that said holding device (13) is detachably connected to said test chamber (11).
9. The windscreen durability testing device according to claim 8, wherein said clamping device (13) comprises: the device comprises a first-stage clamping tool and a second-stage clamping tool which is detachably connected with the first-stage clamping tool and is used for clamping the windshield;
a sealing element is arranged on the edge of the first-stage clamping tool connected with the test box (11);
sealing parts are respectively arranged at the positions where the second-stage clamping tool is connected with the first-stage clamping tool and the windshield;
the clamping device (13) is also provided with a sliding assembly (131) detachably connected with the first-stage clamping tool;
the sliding assembly (131) comprises: the device comprises a support (1311) connected with the primary clamping tool, a pulley (1312) arranged below the support (1311), and a sliding rail (1313) used for supporting the pulley (1312);
the sliding assembly (131) is detachably connected and positioned in the second working chamber (112).
10. The windshield durability test device according to claim 1 or 2, characterized in that the hollow body (11a) comprises: an outer shell (11a1) and an inner liner (11a2) located inside the outer shell (11a 1);
the outer shell (11a1) is made of a cold-rolled steel plate, and the inner liner (11a2) is made of a stainless steel plate;
the first working chamber (111) provides a temperature range of: 0 ℃ to +50 ℃, and the temperature range provided by the second working chamber (112) is as follows: -60 ℃ to +85 ℃;
in a constant state of atmospheric idling, the first working chamber (111) and the second working chamber (112) incorporate a temperature fluctuation degree: less than or equal to plus or minus 0.5 ℃;
in a constant state of atmospheric idle, the first working chamber (111) and the second working chamber (112) combine a temperature uniformity: less than or equal to +/-2 ℃;
in a constant state of atmospheric idle, the first working chamber (111) and the second working chamber (112) incorporate a temperature deviation: less than or equal to +/-2 ℃;
the temperature increase rate of the first working chamber (111) in a state of being charged with 50kg of aluminum: the temperature of 0 ℃ to +50 ℃ is more than or equal to 1 ℃/min;
the cooling rate of the first working chamber (111) in a state of being loaded with 50kg of aluminum is as follows: the temperature of + 50-0 ℃ is more than or equal to 1 ℃/min;
the temperature rise rate of the second working chamber (112) when in a full-range average state of carrying 100kg of aluminum at normal pressure: the temperature of minus 55 ℃ to plus 85 ℃ is more than or equal to 1 ℃/min;
the cooling rate of the second working chamber (112) when in a full-range average state of carrying 100kg of aluminum at normal pressure: the temperature of +85 to-55 ℃ is more than or equal to 1 ℃/min;
when the second working chamber (112) is in a humidity adjusting state, the humidity ranges of the first working chamber (111) and the second working chamber (112) are combined: 20% RH-98% RH;
when the second working chamber (112) is in a humidity adjusting state, the first working chamber (111) and the second working chamber (112) are combined with a humidity deviation: + 3% RH to-3% RH;
humidity uniformity of the second working chamber (112): RH is less than or equal to +/-3 percent;
humidity fluctuation degree of the second working chamber (112): RH is less than or equal to +/-3 percent;
pressure range of the first working chamber (111): normal pressure to 50 kPa;
pressure range of the second working chamber (112): normal pressure;
-pressure deviation of the first working chamber (111): less than or equal to +/-200 Pa;
the rate of change of pressure of the first working chamber (111) satisfies: the time from the pressure value 5593Pa to the pressure value 4085Pa is less than or equal to 40s, the time from the pressure value 4085Pa to the pressure value 2860Pa is less than or equal to 40s, and the time from the pressure value 2860Pa to the pressure value 5593Pa is less than or equal to 40 s;
combined pressure ranges of the first working chamber (111) and the second working chamber (112): normal pressure to 3 kPa;
-the combined pressure deviation of the first working chamber (111) and the second working chamber (112) is selected to be the largest value in the range-5% to 5% or ± 200 Pa;
combined rate of pressure change of the first working chamber (111) and the second working chamber (112): not less than 3 kPa/min;
the combined heating rate of the first working chamber (111) and the second working chamber (112) when in a state of carrying 300kg of aluminum under normal pressure: the temperature of minus 55 ℃ to plus 85 ℃ is more than or equal to 1 ℃/min;
the combined cooling rate of the first working chamber (111) and the second working chamber (112) when the first working chamber and the second working chamber are under the state of carrying 300kg of aluminum under normal pressure: the temperature of +85 to-55 ℃ is more than or equal to 1 ℃/min;
the spraying diameter of the temperature impact unit (125) is 20um, the spraying speed is more than or equal to 1.7m/s, the spraying temperature is-9.4 ℃, and the liquid water content in the spraying is 1g/m3;
In the unloaded state, the temperature impact unit (125) controls the deviation of the temperature during spraying: not more than +/-3.0 ℃;
the temperature impingement unit (125) is operated with a continuous injection time of more than 30 s.
Background
The durability test of the airplane windshield is mainly used for simulating the outer side (outside an engine room) environment and the inner side (inside the engine room) environment of the windshield suffered by the windshield in the flying process of the airplane and examining the capability of the windshield for bearing long-time multi-factor environmental stress. In the flying process of an airplane, the inner side (in an airplane cabin) of a windshield is generally a room at normal temperature and normal pressure, the outer side (outside the airplane cabin) of the windshield is a high-altitude atmospheric environment, the main stress borne by the windshield comprises pneumatic load (pressure difference), temperature and temperature impact, wherein the pneumatic load is the pressure generated by airflow impact on the windshield, the temperature is the atmospheric environment temperature outside the windshield (outside the airplane cabin) and the temperature in the airplane cabin on the inner side of the windshield respectively, and the temperature impact is the supercooled raindrop impact suffered by the outer surface when the airplane flies through a cloud layer.
The windshield durability testing device is mainly used for simulating the pneumatic differential pressure load born by the windshield by providing pressure environments with different sizes for the two sides of the windshield; controlling the temperature and humidity of the inner side and the outer side of the windshield, and simulating the temperature and humidity environment suffered by the inner side and the outer side of the windshield; blowing a supercooled medium to the outside of the windshield simulates the temperature shock experienced by the outside of the windshield.
At present, the durability test of the airplane windshield has not been developed at home, and the durability test of the airplane windshield has already met relevant test standards and has been developed at abroad. But the existing windshield endurance test equipment in foreign countries has the following problems: the pneumatic pressure difference load range is small, the load change control precision is low, and pneumatic loads borne by all positions on the surface of the windshield are uneven; the positive pressure airflow is adopted to destroy the temperature balance of the cabin, so that the control precision of the temperature of the outer surface of the windshield is low; the impact of water mist in the cloud layer on the windshield cannot be effectively simulated by low-temperature impact.
Disclosure of Invention
The invention aims to provide a windshield durability testing device.
To achieve the above object, the present invention provides a windshield durability test device comprising: the device comprises a test box, a clamping device and a control system, wherein the clamping device is used for clamping a windshield;
the test chamber comprises: a first working chamber and a second working chamber;
the clamping device is located between the first working chamber and the second working chamber.
According to one aspect of the invention, the test chamber comprises: the refrigerator comprises a hollow main body, a first refrigerator door and a second refrigerator door, wherein the first refrigerator door and the second refrigerator door are arranged at two opposite ends of the hollow main body;
the clamping device is located in the hollow main body, the clamping device, the hollow main body and the first box door enclose the first working chamber, and the clamping device, the hollow main body and the second box door enclose the second working chamber.
According to one aspect of the invention, the control system is connected to the first and second working chambers, respectively;
the control system is used for controlling the first working chamber to be in a negative pressure environment and the second working chamber to be in a normal pressure environment, and the control system is used for respectively controlling the temperature and the humidity of the first working chamber and the second working chamber.
According to one aspect of the present invention, sealing structures are provided at positions where the hollow main body is closed with the first door and the second door, respectively;
the edge of the first box door and the edge of the second box door are provided with defrosting devices, and/or the positions of the hollow main body, which are respectively contacted with the edges of the first box door and the second box door, are provided with defrosting devices.
According to an aspect of the present invention, the hollow main body is provided with a lighting device and a fan at positions corresponding to the first working chamber and the second working chamber, respectively;
the first box door and the second box door are respectively provided with at least one transparent observation window.
According to one aspect of the invention, the control system comprises: the cabinet body, set up in internal humidity control unit, negative pressure control unit, the temperature control unit of cabinet, set up respectively in first studio with data acquisition sensor in the second studio, the temperature strikes the unit, set up in radiator fan and controller on the cabinet body.
According to one aspect of the invention, the humidity control unit comprises: a humidifier and a water tank;
the negative pressure control unit includes: a vacuum pump;
the temperature control unit includes: the system comprises a compressor, an oil separator, a condenser, an expansion container, a plate heat exchanger and a heater;
the data acquisition sensor includes: temperature sensors, humidity sensors and pressure sensors;
the temperature impact unit includes: water pump, nozzle and axial fan.
According to one aspect of the invention, the holding device is detachably connected to the test chamber.
According to an aspect of the invention, the clamping device comprises: the device comprises a first-stage clamping tool and a second-stage clamping tool which is detachably connected with the first-stage clamping tool and is used for clamping the windshield;
a sealing element is arranged on the edge of the first-stage clamping tool connected with the test box;
and sealing parts are respectively arranged at the positions where the second-stage clamping tool and the first-stage clamping tool are connected with the windshield.
According to one aspect of the invention, the clamping device is further provided with a sliding assembly detachably connected with the first-stage clamping tool;
the sliding assembly includes: the support is connected with the first-stage clamping tool, the pulley is arranged below the support, and the sliding rail is used for supporting the pulley.
According to one aspect of the invention, the slide assembly is removably connectively located within the second working chamber.
According to one aspect of the invention, the hollow body comprises: an outer shell and an inner liner located inside the outer shell;
the shell is made of cold-rolled steel plates, and the lining is made of stainless steel plates.
According to one aspect of the invention, the first working chamber provides a temperature range of: 0 ℃ to +50 ℃, and the temperature range provided by the second working chamber is as follows: minus 60 ℃ to plus 85 ℃.
According to one aspect of the invention, in a constant state of no load at normal pressure, the first working chamber and the second working chamber combine a temperature fluctuation degree: less than or equal to plus or minus 0.5 ℃;
when the working chamber is in a constant state of normal pressure and no load, the temperature uniformity of the first working chamber and the second working chamber is combined: less than or equal to +/-2 ℃;
when the working chamber is in a constant state of normal pressure no load, the temperature deviation of the first working chamber and the second working chamber is combined: is less than or equal to +/-2 ℃.
According to one aspect of the present invention, in a state of being charged with 50kg of aluminum, the temperature increase rate of the first working chamber is: the temperature of 0 ℃ to +50 ℃ is more than or equal to 1 ℃/min;
the cooling rate of the first working chamber in a state of being loaded with 50kg of aluminum: the temperature of + 50-0 ℃ is more than or equal to 1 ℃/min.
According to one aspect of the invention, the temperature rise rate of the second working chamber is, at the full average state of the normal pressure loaded with 100kg of aluminum: the temperature of minus 55 ℃ to plus 85 ℃ is more than or equal to 1 ℃/min;
when the second working chamber is in a whole-course average state of carrying 100kg of aluminum under normal pressure, the temperature reduction rate of the second working chamber is as follows: the temperature of +85 to-55 ℃ is more than or equal to 1 ℃/min.
According to an aspect of the present invention, when the second working chamber performs the humidity adjustment state, the humidity ranges of the first working chamber and the second working chamber are combined: 20% RH-98% RH;
when the second working chamber is in a humidity adjusting state, the humidity deviation of the first working chamber and the humidity deviation of the second working chamber are combined: + 3% RH-3% RH.
According to one aspect of the invention, the humidity uniformity of the second working chamber is: RH is less than or equal to +/-3 percent;
humidity fluctuation degree of the second working chamber: RH is less than or equal to +/-3 percent.
According to one aspect of the invention, the pressure range of the first working chamber is: normal pressure to 50 kPa;
pressure range of the second working chamber: normal pressure;
pressure deviation of the first working chamber: less than or equal to +/-200 Pa;
the rate of change of pressure of the first working chamber satisfies: the time to change from pressure value 5593Pa to pressure value 4085Pa is less than or equal to 40s, the time to change from pressure value 4085Pa to pressure value 2860Pa is less than or equal to 40s, and the time to change from pressure value 2860Pa to pressure value 5593Pa is less than or equal to 40 s.
According to one aspect of the invention, the combined pressure range of the first working chamber and the second working chamber is: normal pressure to 3 kPa;
the maximum combined pressure deviation of the first working chamber and the second working chamber is selected from a range of-5% or a value within +/-200 Pa;
combined rate of pressure change of the first working chamber and the second working chamber: not less than 3 kPa/min.
According to one aspect of the present invention, in a state of being loaded with 300kg of aluminum at normal pressure, the combined temperature increase rate of the first working chamber and the second working chamber is: the temperature of minus 55 ℃ to plus 85 ℃ is more than or equal to 1 ℃/min;
when the aluminum alloy is in a state of carrying 300kg of aluminum under normal pressure, the combined cooling rate of the first working chamber and the second working chamber is as follows: the temperature of +85 to-55 ℃ is more than or equal to 1 ℃/min.
According to the inventionIn one aspect, the spraying diameter of the temperature impact unit is 20um, the spraying speed is more than or equal to 1.7m/s, the spraying temperature is-9.4 ℃, and the liquid water content in the spraying is 1g/m3;
In the no-load state, the temperature control deviation of the temperature impact unit during spraying is as follows: not more than +/-3.0 ℃;
the continuous injection time of the temperature impingement unit during operation is higher than 30 s.
According to one scheme of the invention, the windshield durability testing device can be suitable for various types of windshield durability tests, and can simulate the outer side environment and the inner side environment of the windshield suffered by the windshield in the aircraft flying process, thereby being beneficial to checking the capability of the windshield for bearing long-time multi-factor environmental stress and effectively verifying the durability of the windshield.
According to the scheme of the invention, the windshield durability test device can accurately obtain the evaluation on the structure and performance of the windshield, further provides basis for subsequent improvement and reliability test of other windshields, and is beneficial to effectively improving the quality of the windshield and promoting the development of localization of an airborne windshield.
According to one scheme of the invention, the clamping device is arranged in the test box, so that the durability test of the windshield in a closed environment can be realized, and the influence of the external environment on the test precision is effectively eliminated. Simultaneously, with the mode of clamping device setting in the proof box, can also realize the simulation to the different practical application environment of the inside and outside both sides of windscreen to make the test result more be close to reality, make the test result more accurate.
According to one scheme of the invention, the testing device adopts a method of respectively controlling two boxes to carry out the durability test of the windshield, wherein the pneumatic load adopts a negative pressure-normal pressure mode, the precision of the durability test of the windshield is effectively improved, the variation ranges of temperature, humidity, air pressure load, temperature impact and the like are large, and different types of durability tests can be met. Particularly, the low-temperature impact test is carried out by a spray type method, so that the low-temperature impact effect is effectively ensured.
According to one scheme of the invention, a first working chamber and a second working chamber in the testing device can independently carry out testing tasks, wherein the first working chamber can carry out temperature, low air pressure and other parameter testing tasks, and the second working chamber can carry out temperature, humidity and other parameter testing tasks; and the first working chamber and the second working chamber can also combine and carry out parameter test tasks such as temperature, humidity, low air pressure and the like. The multiple testing modes of the invention are directed at different windshields, and the multiple testing modes can meet the testing requirements, and have high flexibility and good applicability.
According to one scheme of the invention, the tool installation in the testing device adopts a two-stage tool mode, so that the durability test of the windshield can be carried out aiming at windshields with different sizes and shapes, and the applicability is high; in addition, still adopt the mode of slide rail to carry out the frock loading and unloading, promoted experimental production efficiency greatly.
Drawings
Fig. 1 is a perspective view schematically showing a windshield durability testing apparatus according to an embodiment of the present invention;
fig. 2 is a structural view schematically showing a windshield durability testing apparatus according to an embodiment of the present invention;
FIG. 3 is a block diagram schematically illustrating a windshield endurance testing apparatus control system according to one embodiment of the present invention;
fig. 4 is a view schematically showing the internal structure of a first working chamber of a windshield endurance testing apparatus according to an embodiment of the present invention;
fig. 5 is a view schematically showing the internal structure of a second working chamber of a windshield endurance testing apparatus according to an embodiment of the present invention;
fig. 6 is a view schematically showing an installation structure of a temperature impact unit in a windshield durability test apparatus according to an embodiment of the present invention.
Detailed Description
In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments will be briefly described below. It is obvious that the drawings in the following description are only some embodiments of the invention, and that for a person skilled in the art, other drawings can be derived from them without inventive effort.
In describing embodiments of the present invention, the terms "longitudinal," "lateral," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in an orientation or positional relationship that is based on the orientation or positional relationship shown in the associated drawings, which is for convenience and simplicity of description only, and does not indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and thus, the above-described terms should not be construed as limiting the present invention.
The present invention is described in detail below with reference to the drawings and the specific embodiments, which are not repeated herein, but the embodiments of the present invention are not limited to the following embodiments.
As shown in fig. 1, according to an embodiment of the present invention, a windshield durability test apparatus of the present invention includes: a test chamber 11, a holding device 13 for holding the windshield, and a control system 12 connected to the test chamber 11. In the present embodiment, the test chamber 11 includes: a first working chamber 111 and a second working chamber 112; the clamping device 13 is located between the first working chamber 111 and the second working chamber 112.
Through setting up clamping device 13 in the proof box, can realize the durable test of windscreen in airtight environment like this, effectively eliminated external environment to the influence of measuring accuracy. Simultaneously, with the mode of clamping device setting in the proof box, can also realize the simulation to the different practical application environment of the inside and outside both sides of windscreen to make the test result more be close to reality, make the test result more accurate.
As shown in fig. 1, according to one embodiment of the present invention, test chamber 11 includes: a hollow main body 11a, and a first door 11b and a second door 11c provided at opposite ends of the hollow main body 11 a. In the present embodiment, the first door 11b and the second door 11c are connected to the hollow main body 11a by a single-opening hinge door. In the present embodiment, the clamping device 13 is located in the hollow main body 11a, and the clamping device 13, the hollow main body 11a and the first door 11b enclose a first working chamber 111, and the clamping device 13, the hollow main body 11a and the second door 11c enclose a second working chamber 112.
Referring to fig. 1, 2 and 3, according to one embodiment of the present invention, the control system 12 is connected to the first working chamber 111 and the second working chamber 112, respectively. In the present embodiment, the control system 12 is used to control the first working chamber 111 to be in a negative pressure environment and the second working chamber 112 to be in a normal pressure environment, and the control system 12 is used to control the temperature and humidity of the first working chamber 111 and the second working chamber 112, respectively.
As shown in fig. 1, according to an embodiment of the present invention, sealing structures are provided at positions where the hollow main body 11a is closed with the first door 11b and the second door 11c, respectively. In the embodiment, the sealing structure adopts the double-layer silicon rubber sealing strip, so that the sealing structure has high and low temperature resistance, ageing resistance and good sealing performance.
In the present embodiment, the edges of the first and second doors 11b and 11c are provided with the defrosting means, and/or the hollow main body 11a is provided with the defrosting means at a position where it contacts the edges of the first and second doors 11b and 11c, respectively. By providing the defrosting means at the edge of the door 11b, 11c and/or the contact position of the hollow main body 11a with the closed position of the door 11b, 11c, it is possible to effectively prevent dew condensation or frost formation at the edge positions of the hollow main body 11a and the door 11b, 11c during a low temperature test. In the present embodiment, the defrosting device is an electrothermal defrosting device.
As shown in fig. 1, according to an embodiment of the present invention, the hollow body 11a is provided with a lighting device and a fan at positions corresponding to the first working chamber 111 and the second working chamber 112, respectively. In the present embodiment, the first door 11b and the second door 11c are each provided with at least one transparent observation window.
Through the arrangement, the test states in the working rooms can be observed in time.
Referring to fig. 2 and 3, 4, 5, and 6, according to an embodiment of the present invention, the control system 12 includes: the cabinet body, the humidity control unit 121, the negative pressure control unit 122 and the temperature control unit 123 which are arranged in the cabinet body, the data acquisition sensor 124 which is respectively arranged in the first working chamber 111 and the second working chamber 112, the temperature impact unit 125, the heat radiation fan 126 which is arranged on the cabinet body and the controller 127.
In the present embodiment, the humidity control unit 121 includes: a humidifier 1211 and a water tank 1212. The humidifier 1211 is connected to the water tank 1212. In the present embodiment, there are 4 humidifiers 1211 connected to the first working chamber 111 and the second working chamber 112, respectively, and the first working chamber 111 or the second working chamber 112 can be humidified independently or the first working chamber 111 and the second working chamber 112 can be humidified together under the control of the controller 127.
In the present embodiment, the negative pressure control unit 122 includes: a vacuum pump 1221. In the present embodiment, the vacuum pump 1221 is connected to only the first working chamber 111, and is used for realizing a negative pressure environment in the first working chamber 111 under the control of the controller 127 during the test.
In the present embodiment, the temperature control unit 123 includes: a compressor 1231, an oil separator 1232, a condenser 1233, an expansion vessel 1234, a plate heat exchanger 1235, and a heater. In the present embodiment, the compressor 1231, the oil separator 1232, the condenser 1233, the expansion vessel 1234 and the plate heat exchanger 1235 are connected to each other to achieve a cooling effect, and are connected to the first working chamber 111 and the second working chamber 112 through the air ducts, respectively, so that the cooling effect can be achieved in the first working chamber 111 and the second working chamber 112, respectively, under the control of the controller 127. Of course, it can also achieve the dehumidification effect on the environment in the first working chamber 111 and the second working chamber 112 through the air duct, and further achieve the overall humidification and dehumidification functions in combination with the humidifier 1211. In the present embodiment, the heaters in the temperature control unit 123 are provided at the bottom of the first and second working chambers 111 and 112, and thus the individual temperature control and the combined temperature control of the first and second working chambers 111 and 112 by the temperature control unit 123 are realized.
In the present embodiment, the data collection sensor 124 includes: temperature sensor 1241, humidity sensor 1242 and pressure sensor; through the arrangement, the temperature, the humidity and the pressure in the first working chamber 111 and the second working chamber 112 can be respectively acquired, so that the data of the whole test process is more accurate.
In the present embodiment, the temperature impact unit 125 includes: a water pump, a nozzle 1251 and an axial fan 1252.
Referring to fig. 1, 5 and 6, according to one embodiment of the present invention, the holding device 13 is detachably connected to the test chamber 11. In the present embodiment, the clamping device 13 includes: the device comprises a first-stage clamping tool and a second-stage clamping tool which is detachably connected with the first-stage clamping tool and is used for clamping a windshield; in the embodiment, a sealing element is arranged on the edge of the first-stage clamping tool connected with the test box 11; and sealing parts are respectively arranged at the positions where the second-stage clamping tool is connected with the first-stage clamping tool and the windshield. In this embodiment, the sealing elements used are not flexible sealing structures made of elastic material, which ensures that the connection is free of gaps, so as to ensure that the first working chamber 111 and the second working chamber 112 are completely isolated, i.e. no air leakage occurs. In this embodiment, a plurality of threaded holes are formed in the connecting position of the first-stage clamping tool and the second-stage clamping tool, so that the second-stage clamping tool can be quickly installed. In this embodiment, the shape of the position where the first-stage clamping tool is installed on the second-stage clamping tool is fixed, and the edge of the connecting position of the second-stage clamping tool and the windshield is matched with the appearance structure of the windshield, namely, the size and the style of the connecting position of the second-stage clamping tool and the windshield are determined according to the windshield.
Referring to fig. 1, 5 and 6, according to an embodiment of the present invention, the clamping device 13 is further provided with a sliding assembly 131 detachably connected to the first stage clamping tool. In the present embodiment, the slide assembly 131 includes: a bracket 1311 connected to the first stage clamping tool, a pulley 1312 disposed below the bracket 1311, and a slide rail 1313 for supporting the pulley 1312; in this embodiment, the support 1311 is a frame structure. Through the adjustment of support 1311 and first order centre gripping frock hookup location, can adjust the height of first order centre gripping frock, make things convenient for the pulley to get into the slide rail, ensure that the frock loads and unloads smoothly.
Referring to fig. 1, 5 and 6, according to an embodiment of the present invention, a sliding assembly 131 is detachably connected to the second working chamber 112.
As shown in fig. 1, according to an embodiment of the present invention, the hollow body 11a includes: outer shell 11a1 and inner liner 11a2 positioned inside outer shell 11a 1. In the present embodiment, the outer case 11a1 is made of a cold-rolled steel sheet, and the surface thereof is subjected to acid pickling and phosphating, and then is subjected to electrostatic spraying, thereby having an antirust function. The liner 11a2 is made of stainless steel plate and all seams are welded using inert gas welding.
According to one embodiment of the present invention, the controller 127 is used to control the environmental conditions in the first and second working chambers, respectively. In the present embodiment, the controller 127 includes a chinese color liquid crystal touch human-machine interface, a key panel, and a high-performance programmable control unit. In the present embodiment, the temperature, humidity, and pressure conditions can be directly input, displayed, and controlled. In the present embodiment, the controller 127 adopts a man-machine conversation method, and has an automatic, intelligent, and humanized design. The temperature and humidity are respectively controlled by adopting a control mode of two-way input and two-way output, and test parameters, a program curve, working time, a heater, a humidifier, a refrigerating unit and the working state of a fan can be displayed and set. Meanwhile, the automatic operation of a test program and the PID parameter self-tuning function are realized; the heating system, the humidifying/dehumidifying system, the refrigerating unit, the circulating fan, the overtemperature alarm and other subsystems can be automatically combined to work, so that the high control quality of the whole temperature/humidity control system is ensured. It should be noted that the controller 127 in this embodiment may be provided corresponding to the first working chamber and the second working chamber, respectively.
According to one embodiment of the invention, the first working chamber 111 provides a temperature range of: 0 ℃ to +50 ℃, and the temperature range provided by the second working chamber 112 is: minus 60 ℃ to plus 85 ℃.
According to one embodiment of the invention, in the constant state of atmospheric unloaded, the first working chamber 111 and the second working chamber 112 incorporate a temperature fluctuation degree: not more than plus or minus 0.5 ℃ (namely in the range of minus 0.5 ℃ to 0.5 ℃); in the present embodiment, the merging temperature refers to a temperature at which the first working chamber and the second working chamber are merged into one large working chamber after the baffle plate is removed;
in the constant state of atmospheric idle, the first working chamber 111 and the second working chamber 112 combine the temperature uniformity: less than or equal to +/-2 ℃;
in the constant state of normal pressure idling, the first working chamber 111 and the second working chamber 112 incorporate a temperature deviation: is less than or equal to +/-2 ℃.
According to one embodiment of the present invention, in a state of being loaded with 50kg of aluminum, the temperature increase rate of the first working chamber 111: the temperature of 0 ℃ to +50 ℃ is more than or equal to 1 ℃/min;
in the state of being charged with 50kg of aluminum, the cooling rate of the first working chamber 111: the temperature of + 50-0 ℃ is more than or equal to 1 ℃/min.
According to one embodiment of the present invention, the temperature rise rate of the second working chamber 112 at the full average state of the normal pressure loaded with 100kg aluminum: the temperature of minus 55 ℃ to plus 85 ℃ is more than or equal to 1 ℃/min; in the present embodiment, the global average means that when the temperature is increased or decreased from one stage to another stage, another target value is not set in the middle.
The cooling rate of the second working chamber 112 at the full average state of the atmospheric pressure loaded with 100kg of aluminum: the temperature of +85 to-55 ℃ is more than or equal to 1 ℃/min.
According to an embodiment of the present invention, when the second working chamber 112 is in the humidity adjustment state, the first working chamber 111 and the second working chamber 112 combine the humidity ranges: 20% RH-98% RH; in this embodiment, the merging of the humidity is the humidity of the working chamber after the two working chambers are changed into one working chamber without the intermediate baffle.
When the second working chamber 112 is in the humidity adjustment state, the humidity deviation between the first working chamber 111 and the second working chamber 112 is as follows: + 3% RH-3% RH.
According to one embodiment of the present invention, the humidity uniformity of the second working chamber 112 is: RH is less than or equal to +/-3 percent;
humidity fluctuation degree of the second working chamber 112: RH is less than or equal to +/-3 percent.
According to one embodiment of the invention, the pressure range of the first working chamber 111 is: normal pressure to 50 kPa;
pressure range of the second working chamber 112: normal pressure;
pressure deviation of the first working chamber 111: less than or equal to +/-200 Pa;
the rate of change of the pressure of the first working chamber 111 satisfies: the time to change from pressure value 5593Pa to pressure value 4085Pa is less than or equal to 40s, the time to change from pressure value 4085Pa to pressure value 2860Pa is less than or equal to 40s, and the time to change from pressure value 2860Pa to pressure value 5593Pa is less than or equal to 40 s.
According to one embodiment of the invention, the combined pressure range of the first working chamber 111 and the second working chamber 112 is: normal pressure to 3 kPa;
combined pressure deviation of the first working chamber 111 and the second working chamber 112: less than or equal to plus or minus 5% (or 200Pa, maximum value is taken), namely the maximum value of the pressure deviation in the range of-5 to 5 percent or plus or minus 200Pa is selected;
combined pressure change rate of the first working chamber 111 and the second working chamber 112: not less than 3 kPa/min.
According to one embodiment of the present invention, in a state of carrying 300kg of aluminum at normal pressure, the combined temperature increase rate of the first working chamber 111 and the second working chamber 112 is: the temperature of minus 55 ℃ to plus 85 ℃ is more than or equal to 1 ℃/min;
the combined cooling rate of the first working chamber 111 and the second working chamber 112 when in the state of carrying 300kg of aluminum under normal pressure: the temperature of +85 to-55 ℃ is more than or equal to 1 ℃/min.
According to one embodiment of the invention, the temperature impact unit 125 has a spray diameter of 20um, a spray velocity of 1.7m/s or more, a spray temperature of-9.4 ℃, and a liquid water content of 1g/m in the spray3;
In the unloaded state, the temperature impact unit 125 controls the deviation of the temperature during spraying: not more than +/-3.0 ℃;
the continuous injection time of the temperature impingement unit 125 during operation is higher than 30 s.
To further illustrate the present invention, the type of test used to perform windshield testing in the present invention is further described.
Temperature control test: the first working chamber 111 and the second working chamber 112 are provided with independent heaters and refrigeration units, the temperatures of the first working chamber 111 and the second working chamber 112 are controlled respectively, and meanwhile, high-precision Pt100 armored platinum resistors are adopted for accurate temperature measurement and temperature control. The controller sets target temperatures and other parameters corresponding to the first working chamber 111 and the second working chamber 112, the plate heat exchanger is started when the temperature is raised, the refrigerating unit is started when the temperature is lowered, and the air after temperature change circularly flows from the air inlets and the air return inlets of the first working chamber 111 and the second working chamber 112 respectively until the set target temperatures are reached.
Temperature and humidity control test: the first working chamber 111 and the second working chamber 112 are provided with independent humidifiers, the temperature control process is the same as the above section, the controller adopts a control mode of two-path input and two-path output to control the temperature and the humidity respectively, can set the working states of test parameters, program curves, a heater, a refrigerating unit and a fan, and can automatically combine subsystems such as a heating system plate heat exchanger, the refrigerating unit and a circulating fan in a cavity to work, thereby ensuring the high control quality of the whole temperature/pressure control system.
And (3) vacuum negative pressure test: the first working chamber 111 can be used alone for the low pressure test, and the first working chamber 111 and the second working chamber 112 can be combined for the low pressure test. And the controller automatically adjusts the opening and closing of the vacuum pump according to the set pressure target pressure and speed values. The controller detects real-time pressure signals from a pressure sensor arranged in the 111 cavity of the first working chamber, compares the real-time pressure signals with set pressure signals after signal processing and PID operation, and intelligently controls the opening and closing of the vacuum pump according to different pressure working conditions of the system. When the set target pressure value is smaller, the vacuum pump is continuously started; when the set pressure value is larger, the controller automatically controls the opening and closing of the vacuum pump.
And (3) low-temperature impact test: the shower head and the axial flow fan in the low temperature impact unit are installed to the second working chamber 112, as shown in fig. 6. The low-temperature impact test parameters are set through the controller of the second working chamber 112, and the water spraying time and the temperature of the water spraying cabin are set. The refrigerating system carries out refrigeration treatment on water, forms water mist under the strong pressure of the water pump unit, accelerates the water mist through the axial flow fan, and directly forms mist drops to the tested piece to spray, so that the low-temperature impact test is completed.
The foregoing is merely exemplary of particular aspects of the present invention and devices and structures not specifically described herein are understood to be those of ordinary skill in the art and are intended to be implemented in such conventional ways.
The above description is only one embodiment of the present invention, and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.
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