WO2016119248A1 - 一种电子烟雾化器通气性能测试装置及方法 - Google Patents
一种电子烟雾化器通气性能测试装置及方法 Download PDFInfo
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- WO2016119248A1 WO2016119248A1 PCT/CN2015/072023 CN2015072023W WO2016119248A1 WO 2016119248 A1 WO2016119248 A1 WO 2016119248A1 CN 2015072023 W CN2015072023 W CN 2015072023W WO 2016119248 A1 WO2016119248 A1 WO 2016119248A1
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- axis moving
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- atomizer
- moving head
- plate
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01M—TESTING STATIC OR DYNAMIC BALANCE OF MACHINES OR STRUCTURES; TESTING OF STRUCTURES OR APPARATUS, NOT OTHERWISE PROVIDED FOR
- G01M3/00—Investigating fluid-tightness of structures
- G01M3/02—Investigating fluid-tightness of structures by using fluid or vacuum
- G01M3/04—Investigating fluid-tightness of structures by using fluid or vacuum by detecting the presence of fluid at the leakage point
- G01M3/06—Investigating fluid-tightness of structures by using fluid or vacuum by detecting the presence of fluid at the leakage point by observing bubbles in a liquid pool
- G01M3/08—Investigating fluid-tightness of structures by using fluid or vacuum by detecting the presence of fluid at the leakage point by observing bubbles in a liquid pool for pipes, cables or tubes; for pipe joints or seals; for valves; for welds
Definitions
- the present invention relates to the field of electronic cigarette technology, and in particular, to an electronic cigarette atomizer ventilation performance testing apparatus and method.
- Electronic cigarette is a relatively common artificial electronic cigarette product, mainly used to quit smoking and replace cigarettes; the structure of electronic cigarette mainly includes battery rod and atomizer; when the user's smoking action is detected, the battery rod is fog
- the power supply of the chemical device causes the atomizer to be in an open state; when the atomizer is turned on, the heating wire of the atomizer heats up, and the smoke oil is evaporated by heat to form an aerosol that simulates the smoke, thereby allowing the user to absorb electrons.
- the soot has a feeling similar to the smoke. It can be seen that the key point of whether the user can smoke smoothly is: How to detect the user's smoking action, to start the atomizer through the smoking action, so that the user can smoothly smoke the smoke.
- the atomizer is provided with a nozzle and a vent pipe connected to the nozzle.
- a negative pressure is formed in the snorkel; the airflow is under the negative pressure from the bottom of the atomizer (ie, opposite the nozzle) or the side end enters the snorkel and carries the aerosolized aerosol smoke to the user's mouth.
- E-cigarettes generally determine whether the user is smoking by detecting the negative pressure value in the ventilating tube.
- the nebulizer of the electronic cigarette product may have defective products, which may cause the electronic cigarette to fail to work normally.
- the nebulizer vent tube is not sufficiently sealed. When the user smokes, it cannot form enough negative pressure in the vent tube; or the nebulizer vent tube is blocked, and the external airflow cannot enter the atomizer.
- the aeration device is subjected to a suction operation by manually using a silicone glue nozzle to perform the aeration performance test of the atomizer.
- the nebulizer ventilation performance test is performed, the test efficiency is low, and the human mouth suction instability is poor, and the measurement suction cannot be standardized.
- the present invention is directed to the technical problems existing in the prior art, by manually performing a nebulizer ventilation performance test, low test efficiency, and poor consistency of test suction instability, and providing an electronic aerosolizer ventilation performance test device and method , achieving constant pumping in the test , to form a constant negative pressure suction
- the atomizer performs the inhalation test, which makes the test suction force consistent and the test efficiency improved.
- the present invention is directed to the technical problems existing in the prior art, by manually performing a nebulizer ventilation performance test, low test efficiency, and poor test suction instability consistency, and providing an electronic cigarette atomizer ventilation performance test device and method Achieving a constant suction in the test , to form a constant vacuum suction force to perform aspiration test on a plurality of atomizers, so that the test suction is consistent and the test efficiency is improved.
- an embodiment of the present invention provides an electronic cigarette aerator venting performance testing device for automatically testing a row-by-row atomizer for a whole-plate atomizer discharged on an atomizer carrier plate.
- Performance testing devices include: xyz three-axis platform, vacuum generation system and controller;
- the xyz triaxial platform includes: a platform base, a test beam fixedly connected to the platform base, and a y-axis moving plate slidably disposed on the platform base, movably disposed on the test beam An X-axis moving head, a z-axis moving head disposed on the X-axis moving head and movable up and down relative to the X-axis moving head, and a fixed portion disposed at an end of the z-axis moving head and the vacuum a suction cup assembly in which system communication occurs;
- the controller is configured to perform an atomizer ventilation performance test, and an atomizer carrier plate on which the whole plate atomizer is discharged is fixed on the y-axis moving plate, and the X axis After the moving head is in a position corresponding to the test station, starting and controlling the movement of the y-axis moving plate and the z-axis moving head to align the light sucker assembly and lightly press at least the whole plate atomizer A row of atomizers, which in turn causes the vacuum generating system to perform aeration performance test on the at least one row of atomizers.
- the ventilation performance testing device further includes: being disposed in the platform base and drivingly connected to the corresponding the y-axis moving plate, the X-axis moving head, and the z-axis moving head respectively a drive assembly, the drive assembly is electrically connected to the controller; the controller is configured to control the drive assembly to sequentially drive the y-axis moving plate to move the whole plate atomizer along the platform base to
- the test station drives the X-axis moving head to move along the test beam to a position corresponding to the test station, and drive the z-axis moving head to face the entire plate on the test station.
- the device moves to achieve alignment of the suction cup assembly and lightly press at least one row of atomizers of the entire plate atomizer.
- the driving component includes a first driving structure drivingly connected to the y-axis moving plate, a second driving structure drivingly connected to the X-axis moving head, and the z-axis moving head Drive connected third drive Moving structure
- the controller is respectively connected to the first driving structure, the second driving structure and the third driving structure, and the controller is further configured to ventilate ventilation in the at least one row of atomizers After the performance test is completed, controlling the z-axis moving head and the y-axis moving plate to move the suction cup assembly to at least one row of atomizers adjacent to the at least one row of atomizers for ventilation Performance test until all the nebulizers of the whole plate have been tested.
- the test beam comprises: two vertical beams and columns extending vertically upward along two sides of one end of the platform base, and a fixed connection connecting the top ends of the two vertical beams and columns with the platform Horizontal beams and columns parallel to the base;
- the y-axis moving plate is a sliding plate, and the first driving structure is connected under the sliding plate;
- the X-axis moving head is in an inverted L shape, one end of the X-axis moving head is movably connected to the horizontal beam column, and the other end of the X-axis moving head extends toward the testing station,
- the second driving structure is disposed in the horizontal beam and column;
- the z-axis moving head is disposed on the other end of the X-axis moving head, and the end of the z-axis moving head remote from the X-axis moving head is fixedly disposed with the suction cup assembly,
- the third drive structure is disposed in the X-axis moving head.
- the suction cup assembly includes a plurality of test channels
- the number of test channels of the chuck assembly is equal to the number of the at least one row of atomizers on the atomizer carrier plate.
- the vacuum generating system comprises: a plurality of vacuum generators and a plurality of test instruments disposed on the test beam; the number of the plurality of vacuum generators is equal to the number of the test channels And the number of the plurality of test instruments is equal to the number of the test channels;
- the plurality of vacuum generators are in one-to-one correspondence with the plurality of test channels through a plurality of connecting gas pipes; the plurality of vacuum generators are further corresponding to the plurality of test instruments through a plurality of connecting gas pipes [0021] during the performing the nebulizer ventilation performance test, the plurality of vacuum generators sequentially pass through the suction cup assembly and the plurality of atomizer vent pipes of each row of the whole plate atomizer One-to-one correspondence is connected.
- the plurality of test instruments are digital display barometers.
- a nebulizer ventilation performance air pressure threshold is preset in the digital display air pressure meter, and the digital display air pressure is The table includes:
- an alarm unit configured to perform an alarm when the measured negative pressure value exceeds the air pressure threshold.
- all the connecting air pipes are bellows capable of elastically expanding, so that the length of the connecting air pipes meets the movement stroke requirements of the X-axis moving head and the z-axis moving head.
- any one of the plurality of vacuum generators comprises:
- a vacuum generator pressure regulating valve for regulating a negative pressure value in the connecting gas pipe connected to any of the vacuum generators.
- the vacuum generator further includes: an air inlet, an air outlet, and an air suction port;
- the air suction port is respectively connected to one of the plurality of test channels and one of the plurality of test instruments through a three-way valve.
- the vacuum generating system further includes:
- a plurality of air pressure measuring tables for respectively measuring and displaying the negative pressure values of the plurality of air inlets of the plurality of vacuum generators
- the number of the plurality of air pressure measurement tables is less than or equal to the number of the test channels.
- the suction cup assembly comprises: a plurality of air guiding tubes, a plurality of suction cup adapters sleeved on the plurality of air guiding tubes, and one-to-one corresponding to the plurality of air guiding tubes Multiple suction at the lower end of the sealed connection
- the plurality of suction cups for adsorbing at the at least one row of atomizers The upper end is configured to communicate the plurality of air guiding tubes in one-to-one correspondence with the at least one row of atomizer vent holes.
- any one of the plurality of suction cups comprises a pleat buffer structure
- the pleat buffer structure is made of a silicone material.
- an embodiment of the present invention provides a method for testing an aerated performance of an electronic cigarette atomizer, which is applied to the electronic cigarette aerator performance testing device according to the first aspect, wherein the ventilation performance testing device
- the utility model comprises an xyz three-axis platform, a vacuum generating system and a controller; the xyz three-axis platform comprises an X-axis moving head, a y-axis moving plate, a z-axis moving head and a suction cup assembly; and an atomizer carrying the whole plate atomizer
- the plate is fixed on the y-axis moving plate, and the X-axis moving head is at a position corresponding to the testing station, and the method includes the steps of:
- Sl when receiving a start command to perform a nebulizer ventilation performance test, controlling the movement of the y-axis moving plate and the z-axis moving head to align and gently press the suction cup assembly At least one row of atomizers of the plate atomizer;
- the electronic aerosolizer ventilation performance testing device comprises: an xyz triaxial platform, a vacuum generating system and a controller; further, the xyz triaxial platform comprises: a platform base, an X-axis moving head, a y-axis moving plate and a z-axis moving head; wherein the X-axis moving head, the y-axis moving plate, and the z-axis moving head are movable relative to the platform base.
- the suction cup assembly for connecting the nebulizer in the test crucible is set by placing the nebulizer carrier plate on which the whole plate atomizer is discharged on the y-axis moving plate.
- the controller On the z-axis moving head (wherein the chuck assembly is also in communication with a vacuum generating system that generates a test suction), and the X-axis moving head is in a position corresponding to the test station, the controller is activated and Controlling movement of the y-axis moving plate and the z-axis moving head to align and gently press at least one row of atomizers of the whole plate atomizer, thereby enabling the vacuum generating system to The at least one row of nebulizers is tested for aeration performance.
- the suction cup assembly is aligned with the plurality of nebulizers to be detected and tightly connected, so that the vacuum generation system passes through the air passage and the suction cup assembly.
- the electronic cigarette atomizer is connected to simultaneously detect the ventilation performance of the plurality of electronic cigarettes, improve the test efficiency, and the vacuum generation system performs constant pumping in the test , to form a constant negative pressure suction to connect the plurality of mists.
- the device performs the inhalation test, The test suction is consistent and suitable for standardized production.
- FIG. 1 is a schematic structural diagram of an apparatus for testing an aeration performance of an electronic cigarette atomizer according to an embodiment of the present invention
- FIG. 2 is a structural block diagram of a controller, a driving component, and an xyz three-axis platform according to an embodiment of the present invention
- FIG. 3 is a front elevational view of an apparatus for testing an aeration function of an electronic cigarette atomizer provided with a control button according to an embodiment of the present invention
- FIG. 4 is a front view of an electronic cigarette atomizer performance testing device provided with a multi-test channel suction cup assembly according to an embodiment of the present invention
- FIG. 5 is a side rear view of an electronic cigarette atomizer venting performance testing device provided with a multi-vacuum generator according to an embodiment of the present invention
- FIG. 6 is a schematic diagram of a connection of a vacuum generator through a three-way valve to an atomizer and a digital display pressure gauge during a test process according to an embodiment of the present invention
- FIG. 7 is a schematic diagram of a working principle of a vacuum generator according to an embodiment of the present invention.
- FIG. 8 is a schematic structural diagram of a first type of suction cup assembly according to an embodiment of the present invention.
- FIG. 9 is a schematic structural diagram of a second type of suction cup assembly according to an embodiment of the present invention.
- FIG. 10 is a flowchart of a method for testing an aeration performance of an electronic cigarette atomizer according to an embodiment of the present invention.
- FIG. 11 is a schematic diagram of an initial state of an xyz triaxial platform of a ventilation performance testing device according to an embodiment of the present invention.
- FIG. 12 is a schematic view showing alignment of a center hole of a suction cup assembly test channel and a nozzle center hole of a first row atomizer according to an embodiment of the present invention
- FIG. 13 is a schematic view showing the light pressure of the suction cup of the ventilation performance testing device according to the embodiment of the present invention.
- FIG. 14 is a center hole of a test channel of a suction cup assembly of a ventilation performance testing device according to an embodiment of the present invention. Schematic diagram of the center hole of the nozzle of the latter row of atomizers;
- 15 is a schematic diagram of light pressure pressing of a suction cup of a ventilation performance testing device according to an embodiment of the present invention to a last row of atomizers.
- Embodiments of the present invention provide an electronic cigarette atomizer venting performance testing device, which solves the technical problem of manually performing a nebulizer venting performance test in a prior art, which has low testing efficiency and poor consistency of test suction instability. Achieving a constant suction in the test , to form a constant vacuum suction force to perform aspiration test on a plurality of atomizers, so that the test suction is consistent and the test efficiency is improved.
- Embodiments of the present invention provide an electronic cigarette aerator venting performance testing device for performing a row-by-row automatic test on a whole-plate atomizer discharged on an atomizer carrier board, and the venting performance testing device includes The xyz three-axis platform, the vacuum generating system and the controller; the xyz three-axis platform comprises: a platform base, a test beam fixedly connected to the platform base, and a y-axis moving plate slidably disposed on the platform base, An X-axis moving head movably disposed on the test beam, a z-axis moving head disposed on the X-axis moving head and movable up and down relative to the X-axis moving head, and fixedly disposed on the z-axis a suction cup assembly that moves the end of the head and is in communication with the vacuum generating system; the controller is configured to perform an atomizer venting performance test, and the atomizer carrier plate on which the whole plate atom
- the electronic aerosolizer ventilation performance testing device comprises: an xyz three-axis platform, a vacuum generating system and a controller; further, the xyz three-axis platform comprises: a platform base and an X-axis movement a head, a y-axis moving plate and a z-axis moving head; wherein the X-axis moving head, the y-axis moving plate and the z-axis moving head are movable relative to the platform base.
- the suction cup assembly for connecting the nebulizer in the test crucible is set by placing the nebulizer carrier plate on which the whole plate atomizer is discharged on the y-axis moving plate.
- the y-axis moving plate and the z-axis moving head are moved to align and gently press the at least one row of atomizers of the whole plate atomizer And causing the vacuum generating system to perform aeration performance test on the at least one row of atomizers.
- the suction cup assembly is aligned with the plurality of nebulizers to be detected and tightly connected, so that the vacuum generation system passes through the air passage and the suction cup assembly.
- the electronic cigarette atomizer is connected to simultaneously detect the ventilation performance of the plurality of electronic cigarettes, improve the test efficiency, and the vacuum generation system performs constant pumping in the test , to form a constant negative pressure suction to connect the plurality of mists.
- the instrument performs the suction test, and the test suction is consistent, which is suitable for standardized production.
- an embodiment of the present invention provides an electronic cigarette atomizer venting performance testing device for automatically testing a row-by-row atomizer 200 discharged on an atomizer carrier plate 100.
- the ventilation performance testing device comprises: an xyz triaxial platform 1, a vacuum generating system 2 and a controller 3;
- the xyz triaxial platform 1 includes: a platform base 11, a test beam 12 fixedly coupled to the platform base 11, and a y-axis moving plate 111 slidably disposed on the platform base 11, movably disposed on the test beam 12.
- the controller 3 is used to perform the atomizer venting performance test, and the atomizer carrier plate 100 on which the entire plate atomizer 200 is discharged is fixed on the y-axis moving plate 111, and the X-axis moving head 121. After being in a position corresponding to the test station, the y-axis moving plate 111 and the z-axis moving head 122 are activated and controlled to align and gently press at least one row of atomizers of the whole plate atomizer 200. The vacuum generating system 2 is further tested for the aeration performance of the at least one row of atomizers.
- the controller 3 when the number of test channels arranged on the suction cup assembly 123 is greater than or equal to the number of rows of atomizers on the atomizer carrier plate 100, and the X-axis moving head 121 is in the same state The position corresponding to the test station ⁇ , the controller 3 only needs to control the movement of the y-axis moving plate 111 and the z-axis moving head 122, so that the suction cup assembly 1 23 sequentially testing all of the atomizers 200 on the carrier plate 100; the number of test channels disposed on the suction cup assembly 123 is less than the number of rows of atomizers on the atomizer carrier plate 100 (eg, atomizer loading) The number of rows of atomizers on the plate 100 is twice that of the number of test channels provided on the chuck assembly 123.) The controller 3 needs to control the X-axis moving head 121, the y-axis moving plate 111, and the z-axis movement. The head 122 is moved
- the ventilation performance testing device further includes: a set in the platform base 11 and respectively corresponding to the y-axis moving plate 111, the X-axis moving head 121, and the z-axis moving head 122.
- Driving the connected drive component 4 (such as a cylinder or a motor, etc.), the drive component 4 is electrically connected to the controller 3; the controller 3 is used to control the drive component 4 to sequentially drive the y-axis moving plate 111 to atomize the entire plate along the platform base 11, respectively.
- the device 200 moves to the test station, drives the X-axis moving head 121 to move along the test beam 12 to a position corresponding to the test station, and drives the z-axis moving head 122 to face the whole board fog on the test station.
- the chemist 200 moves to effect alignment of the suction cup assembly 123 and lightly press at least one row of atomizers of the entire plate atomizer 200.
- the driving assembly 4 includes a first driving structure 41 drivingly coupled to the y-axis moving plate 111, a second driving structure 42 drivingly coupled to the X-axis moving head 121, and a z-axis.
- the moving head 122 drives the connected third driving structure 43; the controller 3 is connected to the first driving structure 41, the second driving structure 42 and the third driving structure 43, respectively, and the controller 3 is further configured to atomize in the at least one row
- the z-axis moving head 122 and the y-axis moving plate 111 are controlled to move, so that the suction cup assembly 123 is moved to at least one row of atomizers adjacent to the at least one row of atomizers for ventilation performance. Test until the entire plate nebulizer 200 has been tested.
- the test beam 12 includes: two vertical beams and columns 124 extending vertically along two sides of one end portion of the platform base 11, and two vertical beams and columns fixedly connected 12 4 is a horizontal beam column 125 parallel to the platform base 11;
- the y-axis moving plate 111 is a sliding plate, and the first driving structure 41 is connected below the sliding plate;
- the X-axis moving head 121 is inverted L-shaped (as shown in FIG.
- the X-axis moving head 121-end is movably connected to the horizontal beam column 125, the other end of the X-axis moving head 121 extends toward the testing station, and the second driving structure 42 is disposed in the horizontal beam column 125;
- the shaft moving head 122 is disposed on the other end of the X-axis moving head 121.
- the end of the z-axis moving head 122 away from the X-axis moving head 121 is fixedly provided with a chuck assembly 1 23, and the X-axis moving head 121 is provided with a third portion.
- Drive structure 43 is provided.
- the first driving structure 41, the second driving structure 42 or the third driving structure 43 are all a cylinder driving structure or a motor driving structure, etc., driving technology
- the existing mature technology can be used, and will not be repeated here.
- the controller 3 is disposed inside the platform base 11, and includes a control circuit (not shown) of the controller 3.
- the surface of the platform base 11 is disposed.
- the chuck assembly 123 includes a plurality of test channels 5; the number of test channels of the chuck assembly 123 is equal to the number of the at least one row of atomizers on the atomizer carrier plate 100.
- the atomizer carrier plate 100 is provided with 10 rows and 10 columns arranged in an array, a total of 100 grooves for placing the atomizer, for placing 100 atomizers, and a suction cup assembly.
- the y-axis moving plate 111 and the z-axis moving head 122 are controlled to move, so that the 10 test channels of the chuck assembly 123 are aligned and lightly atomized.
- the row of atomizers on the carrier plate 100, and the vacuum generating system 2 is activated to perform aeration performance test on the evacuation of the row of atomizers. After the row of tests is completed, the next row of atomizers is ventilated. Test until all nebulizers on the nebulizer carrier plate 100 have completed the test.
- the vacuum generating system 2 includes: a plurality of vacuum generators 21 (shown in FIG. 5) and a plurality of test instruments 22 disposed on the test beam 12 (as shown in FIG. 4).
- Any one of the plurality of vacuum generators 21 includes: a vacuum generator pressure regulating valve 211 (also shown in FIG. 4) for adjusting a connection to any of the vacuum generators Negative pressure value in the trachea.
- a plurality of vacuum generators 21 are disposed on the back surface of the ventilation performance testing device (as shown in FIG. 5), and a position corresponding to the plurality of vacuum generators 21 on the front surface of the ventilation performance testing device
- a plurality of vacuum generator pressure regulating valves 211 are provided (as shown in FIG. 4).
- the number of the plurality of vacuum generators 21 is equal to the number of the test channels, and the number of the plurality of test instruments 22 and the number of the test channels Equivalent; a plurality of vacuum generators 21 are connected to the plurality of test channels 5 in a one-to-one correspondence through a plurality of connecting gas pipes; the plurality of vacuum generators 21 are further connected to the plurality of test instruments 22 in a one-to-one correspondence through a plurality of connecting gas pipes;
- the length of the connecting air pipe meets the motion stroke requirements of the X-axis moving head 121 and the z-axis moving head 122, wherein all the connecting air pipes can adopt a hose, and preferably, the connecting air pipe is a bellows capable of elastically expanding and contracting; Nebulizer pass During the gas performance test, the plurality of vacuum generators 21 are sequentially in communication with the plurality of atomizer vent pipes of each row of the entire plate atom
- any vacuum generator 21 further includes: an air inlet 212, an air outlet 213, and an air suction port 214; the air suction port 214 is respectively connected to one of the plurality of test channels 5 through the three-way valve 215
- the test channel is in communication with one of the plurality of test instruments 22.
- the arrows indicate the flow direction of the air. Specifically, the compressed air enters the vacuum generator 21 from the air inlet 212 and is ejected from the air outlet 213. This process forms a negative pressure at the vacuum generator suction port 214, and then passes through the tee.
- the valve 215 is divided into two paths, and the test instrument 22 (such as a digital pressure gauge) and the atomizer 200 are separately pumped.
- the aeration performance of the atomizer 200 can be judged by the change in the negative pressure difference displayed by the test meter 22.
- FIG. 6 is a schematic diagram of the working principle of one test channel, and the like for the case of the multi-channel test channel, and will not be repeated here.
- the working principle diagram of any vacuum generator 21 is as shown in FIG. 7, the compressed air passes through the air pipe from the vacuum generator inlet 212 into the vacuum generator 21, and the compressed air enters the diffusion chamber 216 through the ventilation duct.
- the air outlet 213 forms a jet to form a entrainment flow.
- the air in the adsorption chamber 217 is continuously drawn through the check valve 218 to form a certain degree of vacuum, and the vacuum generator suction port 214 forms a negative pressure.
- the negative pressure at the suction port 214 can be adjusted by adjusting the pressure regulating valve 211 to move left and right to reduce or increase the amount of ventilation of the diffusion chamber 216 and the ventilation duct.
- the suction cup assembly 123 includes: a plurality of air guiding tubes 51, a plurality of suction cup adapters 52 correspondingly disposed on the plurality of air guiding tubes 51, and one-to-one correspondence and a plurality of air guiding tubes a plurality of suction cups 53 that are sealingly connected to the lower end of the mold 51; in the process of aligning and lightly pressing the suction cup assembly 123 to at least one row of the atomizers of the whole plate atomizer 200, a plurality of suction cups 53 for adsorbing at the at least one
- the upper end of the atomizer is arranged such that the plurality of air guiding tubes 51 are in one-to-one correspondence with the at least one row of atomizer vent holes; the arrows in Fig.
- each vacuum generator is connected to the vacuum generator through the air guiding tube 51, the suction cup adapter 52, and the suction cup 53 communicating therewith.
- the atomizer is pumped to detect the aeration performance of the atomizer.
- any of the plurality of suction cups 53 A suction cup includes a pleat cushioning structure 54; the suction cup assembly 123 is aligned and lightly pressed against the at least one row of atomizers of the whole plate atomizer 200, and the pleat buffer structure 54 is pressed against the aligned atomizer
- the upper end of the wrinkle buffer structure 54 is made of a silicone material; in addition, in a specific implementation process, the center hole of the suction cup is concentric with the atomizer vent hole and has the same aperture to improve the measurement accuracy.
- the compressed air entering the inlet port 212 of each vacuum generator is from an external pressure controller, and the air pressure value is relatively large (for example, 0.7 bar), and the atomizer ventilating performance measurement is required.
- the air pressure value is 0.3 ( ⁇ 0.05) bar.
- the vacuum generating system 2 further includes: a plurality of air pressure measuring tables 23, a negative pressure value for respectively measuring and displaying the plurality of air inlets 212 of the plurality of vacuum generators 21; a plurality of air pressure regulating valves 24 corresponding to the plurality of air pressure measuring tables 23, for adjusting the plurality of The negative pressure value of the air port 212 (shown in FIG. 6 and FIG.
- the plurality of test instruments 22 all adopt a digital display barometer, and the measurement range of each barometric pressure measurement table 23 is greater than The measurement range of the digital barometer; and, the total number of the plurality of barometric pressure measurement tables 23 is less than or equal to the number of the test channels (ie, less than or equal to the total number of the plurality of digital barometers).
- the total number of the plurality of digital barometers used is twice the total number of the plurality of barometric pressure measurement tables 23, and the ventilation performance testing device has 10 test channels, that is, 10 vacuum generators 21, and input 5 compressed air for the 10 vacuum generators 21, wherein each of the input compressed air is divided into two inlets 212 respectively leading to the two vacuum generators, and Each of the five inputs is respectively provided with a barometric pressure measurement table 23 and a gas pressure regulating valve 24 for preliminary measurement and control of the pressure of the five input compressed air. Further, in the subsequent measurement, a plurality of test instruments 22 are passed.
- the total number of the plurality of air pressure measurement tables 23 may also be equal to the total number of the plurality of test instruments 22, in this case, 10
- the vacuum generator 21 inputs 10 compressed air, and the input 10 compressed airs are respectively corresponding to the intake ports 212 of the 10 vacuum generators.
- the plurality of test instruments 22 are digital display barometers, and are pre-predicted in the digital barometer
- the atomizing device has a gas pressure threshold, such as (-0.3 ⁇ 0.05) bar
- the digital barometer includes: an alarm unit, configured to alarm when the measured negative pressure value exceeds the air pressure threshold; for example, The negative pressure value measured in a pipe by a digital barometer is -0.36 bar ⁇ , and the numerical value displayed by the digital barometer will change color (such as from black to red) and an audible alarm signal will be issued.
- the suction required for the test is generated by the vacuum generating system, and a constant suction is formed by constant pumping, and the constant negative suction is used to the atomizer and the corresponding digital pressure.
- the same table is used for inhalation, and the barometric pressure meter is used to display the air pressure difference to reflect the aeration performance of the nebulizer tested.
- the vacuum generation system is used to generate a batch and consistent test suction, and then Combined with the xyz triaxial platform, the vacuum generator in the vacuum generation system during the test is closely connected with the electronic cigarette or its atomizer through the air passage and the suction cup, and the ventilation performance of the plurality of electronic aerosolizers is improved, and the ventilation performance is improved.
- the test suction is consistent, and is applicable to standardized production; in addition, the suction cup is set With pleated cushion structure, it can effectively prevent the suction cup and the atomizer nozzle surface from being pressed tightly.
- the atomizer is close to the end face of the suction cup, causing poor airtightness and inaccurate measurement between the suction cup and the atomizer nozzle; by using a suction cup having the same hole diameter as that of the atomizer vent hole, The accuracy of the measurement.
- an embodiment of the present invention further provides an electronic cigarette atomizer venting performance testing method, which is applied to the electronic cigarette ventilator performance testing device according to the first embodiment.
- the ventilation performance testing device comprises an xyz triaxial platform 1, a vacuum generating system 2 and a controller 3; the xyz triaxial platform 1 comprises an X-axis moving head 121, a y-axis moving plate 111, a z-axis moving head 122 and a suction cup assembly 123;
- the atomizer carrier plate 100 on which the whole plate atomizer 200 is discharged is fixed on the y-axis moving plate 111, and the x-axis moving head 121 is at a position corresponding to the test station, and the method includes the steps of:
- the atomizer carrier plate 100 is provided with 10 rows and 10 columns arranged in an array, a total of 100 grooves for placing the atomizer, for placing 100 atomizers, the suction cup assembly
- the 123 is provided with 10 test channels corresponding to a row of atomizers on the atomizer carrier 100, and the xyz triaxial platform 1 of the ventilation performance test device is in an initial state (as shown in FIG.
- the carrier plate filled with the atomizer is placed on the y-axis moving plate 111, and by controlling the plurality of control buttons, the X-axis moving head 121 is controlled to drive the z-axis moving head 122 to the right end of the horizontal beam column 125.
- the y-axis moving plate 111 Moving, and controlling the y-axis moving plate 111 to move the atomizer carrier plate 100 on which 100 atomizers are placed in the opposite direction to the extreme end 112, so that the suction cup assembly 123 has 10 suction cup center holes and the first row of fog
- the center hole of the nozzle of the chemical device is aligned (as shown in FIG. 12); then, the z-axis moving head 122 is controlled to move downward (in the direction indicated by the arrow in FIG.
- the number of test channels of the ventilation performance testing device may also be set to 20, 30, etc., and the atomizer carrier plate 100 may be configured to discharge more fog.
- the grooves of the chemical device, such as 200, 300, etc., are not specifically limited herein.
- embodiments of the present invention can be provided as a method, system, or computer program product.
- the present invention may employ an entirely hardware embodiment, an entirely software embodiment, or a combination of soft A form of embodiment of hardware and hardware.
- the present invention may take the form of a computer program product embodied in one or more of which comprises a computer usable storage medium having computer-usable program code (including but not limited to, disk storage, CD-R 0 M, optical memory, etc.).
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Abstract
一种电子烟雾化器通气性能测试装置及方法,所述通气性能测试装置包括:xyz三轴平台(1),真空发生系统(2)和控制器(3);xyz三轴平台(1)包括:平台底座(11),测试梁(12),y轴移动板(111),x轴移动头(121),z轴移动头(122),吸盘组件(123);控制器(3)用于在测试时启动并控制y轴移动板(111)和z轴移动头(122)运动,以使吸盘组件(123)对准并轻压承载板(100)上的雾化器(200),使真空发生系统(2)对雾化器(200)进行通气性能测试;上述测试装置解决了现有技术中雾化器通气性能测试效率低,测试吸力不稳定且一致性差的技术问题,实现了在测试时形成恒定负压吸力对多个雾化器进行吸气测试,测试效率高的技术效果。
Description
说明书 发明名称:一种电子烟雾化器通气性能测试装置及方法 技术领域
[0001] 本发明涉及电子烟技术领域, 尤其涉及一种电子烟雾化器通气性能测试装置及 方法。
背景技术
[0002] 电子烟是一种较为常见的仿真香烟电子产品, 主要用于戒烟和替代香烟; 电子 烟的结构主要包括电池杆和雾化器; 当检测到用户的吸烟动作吋, 电池杆为雾 化器供电, 使雾化器处于幵启状态; 当雾化器幵启后, 雾化器发热丝发热, 烟 油受热蒸发雾化, 形成模拟烟气的气雾, 从而让使用者在吸电子烟吋有一种类 似吸真烟的感觉。 可见, 用户能否顺利吸烟的关键点在于: 如何检测用户的吸 烟动作, 以通过吸烟动作幵启雾化器, 进而使用户能够顺利吸到烟雾。
[0003] 雾化器上设置有吸嘴和与吸嘴相连的通气管, 正常情况下, 当用户吸烟吋, 通 气管中会形成负压; 气流在该负压作用下从雾化器底端 (即与吸嘴相对端) 或 侧端进入通气管, 并携带烟油雾化烟雾流向用户嘴部。 电子烟一般通过检测通 气管中的负压值判断用户是否在吸烟, 但是, 目前电子烟产品多为批量生产, 电子烟产品的雾化器可能存在瑕疵品, 导致电子烟无法正常工作。 例如, 雾化 器通气管密封性不够, 当用户吸烟吋, 无法在通气管形成足够的负压; 或雾化 器通气管阻塞, 外部气流无法进入雾化器等。
[0004] 针对上述批量生产的雾化器存在瑕疵的问题, 在现有技术中, 通过人工利用硅 胶吸嘴对一个个雾化器进行吸气操作, 以进行雾化器的通气性能测试。 但是, 通过此种方式进行雾化器通气性能测试, 测试效率低, 且人嘴吸力不稳定一致 性较差, 无法对测量吸力进行标准化。
技术问题
[0005] 本发明针对现有技术中存在的, 通过人工进行雾化器通气性能测试, 测试效率 低, 测试吸力不稳定一致性差的技术问题, 提供一种电子烟雾化器通气性能测 试装置及方法, 实现了在测试吋进行恒定抽气, 以形成恒定负压吸力同吋对多
个雾化器进行吸气测试, 使得测试吸力一致、 测试效率得到提高的技术效果。 问题的解决方案
技术解决方案
[0006] 本发明针对现有技术中存在的, 通过人工进行雾化器通气性能测试, 测试效率 低, 测试吸力不稳定一致性差的技术问题, 提供一种电子烟雾化器通气性能测 试装置及方法, 实现了在测试吋进行恒定抽气, 以形成恒定负压吸力同吋对多 个雾化器进行吸气测试, 使得测试吸力一致、 测试效率得到提高的技术效果。
[0007] 第一方面, 本发明实施例提供了一种电子烟雾化器通气性能测试装置, 用于对 排放在雾化器承载板上的整板雾化器进行逐排自动测试, 所述通气性能测试装 置包括: xyz三轴平台, 真空发生系统和控制器;
[0008] 所述 xyz三轴平台, 包括: 平台底座, 与所述平台底座固定连接的测试梁, 滑 动设置在所述平台底座上的 y轴移动板, 可移动地设置在所述测试梁上的 X轴移 动头, 设置在所述 X轴移动头上且可相对所述 X轴移动头上下移动的 z轴移动头, 以及固定设置在所述 z轴移动头的端部且与所述真空发生系统连通的吸盘组件;
[0009] 所述控制器用于在进行雾化器通气性能测试吋, 且排放有所述整板雾化器的雾 化器承载板被固定在所述 y轴移动板上, 以及所述 X轴移动头处于与测试工位对 应的位置后, 启动并控制所述 y轴移动板和所述 z轴移动头运动, 以使所述吸盘组 件对准并轻压所述整板雾化器的至少一排雾化器, 进而使所述真空发生系统对 所述至少一排雾化器进行通气性能测试。
[0010] 可选的, 所述通气性能测试装置还包括: 设置在所述平台底座内且分别与对应 的所述 y轴移动板、 所述 X轴移动头和所述 z轴移动头驱动连接的驱动组件, 所述 驱动组件与所述控制器电连接; 所述控制器用于控制所述驱动组件分别依次驱 动所述 y轴移动板沿所述平台底座将所述整板雾化器移动至所述测试工位, 驱动 所述 X轴移动头沿所述测试梁移动至与所述测试工位对应的位置, 以及驱动所述 z 轴移动头朝向所述测试工位上的整板雾化器运动, 以实现所述吸盘组件对准并 轻压所述整板雾化器的至少一排雾化器。
[0011] 可选的, 所述驱动组件包括与所述 y轴移动板驱动连接的第一驱动结构, 与所 述 X轴移动头驱动连接的第二驱动结构, 以及与所述 z轴移动头驱动连接的第三驱
动结构;
[0012] 所述控制器分别与所述第一驱动结构、 所述第二驱动结构和所述第三驱动结构 连接, 所述控制器还用于在所述至少一排雾化器通气性能通气性能测试完成后 , 控制所述 z轴移动头和所述 y轴移动板运动, 以使所述吸盘组件运动到与所述至 少一排雾化器相邻的再至少一排雾化器进行通气性能测试, 直至所述整板雾化 器全部测试完毕。
[0013] 可选的, 所述测试梁包括: 分别沿所述平台底座一端部的两侧向上垂直延伸的 两个垂直梁柱, 以及固定连接所述两个垂直梁柱顶端的与所述平台底座平行的 水平梁柱;
[0014] 所述 y轴移动板为一滑板, 在所述滑板下方连接有所述第一驱动结构;
[0015] 所述 X轴移动头呈倒 L型, 所述 X轴移动头一端与所述水平梁柱可移动连接, 所 述 X轴移动头另一端朝向所述测试工位延伸, 在所述水平梁柱中设置有所述第二 驱动结构;
[0016] 所述 z轴移动头设置在所述 X轴移动头的另一端上, 所述 z轴移动头的远离所述 X 轴移动头的端部固定设置有所述吸盘组件, 在所述 X轴移动头中设置有所述第三 驱动结构。
[0017] 可选的, 所述吸盘组件包括多个测试通道;
[0018] 所述吸盘组件的测试通道数等于所述雾化器承载板上的所述至少一排雾化器的 个数。
[0019] 可选的, 所述真空发生系统包括: 设置在所述测试梁上的多个真空发生器和多 个测试仪表; 所述多个真空发生器的个数与所述测试通道数相等, 且所述多个 测试仪表的个数与所述测试通道数相等;
[0020] 所述多个真空发生器通过多条连接气管一一对应与所述多个测试通道连通; 所 述多个真空发生器还通过多条连接气管一一对应与所述多个测试仪表连通; [0021] 在进行雾化器通气性能测试的过程中, 所述多个真空发生器通过所述吸盘组件 依次与所述整板雾化器的每一排的多个雾化器通气管一一对应相连通。
[0022] 可选的, 所述多个测试仪表均为数显气压表。
[0023] 可选的, 在所述数显气压表中预设有雾化器通气性能气压阈值, 所述数显气压
表包括:
[0024] 报警单元, 用于在测量获得的负压值超过所述气压阈值吋进行报警。
[0025] 可选的, 所有所述连接气管为能够弹性伸缩的波纹管, 以使所述连接气管的长 度均满足所述 X轴移动头和所述 z轴移动头的运动行程需求。
[0026] 可选的, 所述多个真空发生器中的任一真空发生器包括:
[0027] 真空发生器调压阀, 用于调节与所述任一真空发生器相连的连接气管中的负压 值。
[0028] 可选的, 所述任一真空发生器还包括: 进气口、 出气口和抽气口;
[0029] 所述抽气口通过三通阀分别与所述多个测试通道中的一个测试通道和所述多个 测试仪表中的一个测试仪表连通。
[0030] 可选的, 所述真空发生系统还包括:
[0031] 多个气压测量表, 用于分别测量并显示所述多个真空发生器的多个进气口的负 压值;
[0032] 与所述多个气压测量表一一对应的多个气压调节阀, 用于调节所述多个进气口 的负压值;
[0033] 其中, 所述多个气压测量表的个数小于或等于所述测试通道数。
[0034] 可选的, 所述吸盘组件包括: 多个导气管, 一一对应套设在所述多个导气管上 的多个吸盘转接头, 以及一一对应与所述多个导气管的下端密封连接的多个吸
[0035] 在所述吸盘组件向所述整板雾化器的至少一排雾化器对准并轻压的过程中, 所 述多个吸盘用于吸附在所述至少一排雾化器的上端, 以使所述多个导气管与所 述至少一排雾化器通气孔一一对应连通。
[0036] 可选的, 所述多个吸盘中的任一吸盘包括褶皱缓冲结构;
[0037] 在所述吸盘组件向所述整板雾化器的所述至少一排雾化器对准并轻压吋, 所述 褶皱缓冲结构被压附在被对准的雾化器的上端。
[0038] 可选的, 所述褶皱缓冲结构为硅胶材质。
[0039] 第二方面, 本发明实施例还提供了一种电子烟雾化器通气性能测试方法, 应用 于第一方面所述的电子烟雾化器通气性能测试装置中, 所述通气性能测试装置
包括 xyz三轴平台、 真空发生系统和控制器; 所述 xyz三轴平台包括 X轴移动头、 y 轴移动板、 z轴移动头和吸盘组件; 排放有整板雾化器的雾化器承载板固定在所 述 y轴移动板上, 且所述 X轴移动头处于与测试工位对应的位置, 所述方法包括 步骤:
[0040] Sl、 当接收到进行雾化器通气性能测试的启动指令吋, 控制所述 y轴移动板和 所述 z轴移动头运动, 以使所述吸盘组件对准并轻压所述整板雾化器的至少一排 雾化器;
[0041] S2、 启动所述真空发生系统对所述至少一排雾化器进行通气性能通气性能测试
[0042] S3、 在所述至少一排雾化器通气性能通气性能测试完成后, 控制所述 z轴移动 头和所述 y轴移动板运动, 以使所述吸盘组件运动到与所述至少一排雾化器相邻 的再至少一排雾化器进行通气性能测试, 直至所述整板雾化器全部测试完毕。 发明的有益效果
有益效果
[0043] 由于在本发明方案中, 电子烟雾化器通气性能测试装置包括: xyz三轴平台, 真空发生系统和控制器; 进一步, 所述 xyz三轴平台包括: 平台底座、 X轴移动头 、 y轴移动板和 z轴移动头; 其中, 所述 X轴移动头、 所述 y轴移动板和所述 z轴移 动头可相对于所述平台底座运动。 在进行雾化器通气性能测试吋, 通过将排放 有整板雾化器的雾化器承载板固定放置在所述 y轴移动板上, 将用于在测试吋连 接雾化器的吸盘组件设置在所述 z轴移动头上 (其中, 所述吸盘组件还与产生测 试吸力的真空发生系统连通) , 且所述 X轴移动头处于与测试工位对应的位置后 , 所述控制器启动并控制所述 y轴移动板和所述 z轴移动头运动, 以使所述吸盘组 件对准并轻压所述整板雾化器的至少一排雾化器, 进而使所述真空发生系统对 所述至少一排雾化器进行通气性能测试。 也就是说, 在雾化器通气性能测试吋 , 通过结合 xyz三轴平台, 将吸盘组件同吋与多个待检测雾化器对准并紧密连接 , 使得真空发生系统通过气道和吸盘组件与电子烟雾化器进行连通, 可以同吋 检测多个电子烟雾化器的通气性能, 提高了测试效率, 并且真空发生系统在测 试吋进行恒定抽气, 以形成恒定负压吸力对连通的多个雾化器进行吸气测试,
测试吸力一致, 适用于标准化生产。
对附图的简要说明
附图说明
[0044] 为了更清楚地说明本发明实施例或现有技术中的技术方案, 下面将对实施例或 现有技术描述中所需要使用的附图作简单地介绍, 显而易见地, 下面描述中的 附图仅仅是本发明的实施例, 对于本领域普通技术人员来讲, 在不付出创造性 劳动的前提下, 还可以根据提供的附图获得其他的附图。
[0045] 图 1为本发明实施例提供的一种电子烟雾化器通气性能测试装置结构示意图; [0046] 图 2为本发明实施例提供的控制器、 驱动组件以及 xyz三轴平台的结构框图; [0047] 图 3为本发明实施例提供的一种设置有控制按钮的电子烟雾化器通气性能测试 装置的正视图;
[0048] 图 4为本发明实施例提供的一种设置有多测试通道吸盘组件的电子烟雾化器通 气性能测试装置的正视图;
[0049] 图 5为本发明实施例提供的一种设置有多真空发生器的电子烟雾化器通气性能 测试装置的侧后视图;
[0050] 图 6为本发明实施例提供的测试过程中真空发生器通过三通阀与雾化器和数显 气压表的连接示意图;
[0051] 图 7为本发明实施例提供的一种真空发生器工作原理图;
[0052] 图 8为本发明实施例提供的第一种吸盘组件结构示意图;
[0053] 图 9为本发明实施例提供的第二种吸盘组件结构示意图;
[0054] 图 10为本发明实施例提供的一种电子烟雾化器通气性能测试方法流程图; [0055] 图 11为本发明实施例提供的通气性能测试装置的 xyz三轴平台初始状态示意图
[0056] 图 12为本发明实施例提供的通气性能测试装置的吸盘组件测试通道中心孔与第 一排雾化器的吸嘴中心孔对齐示意图;
[0057] 图 13为本发明实施例提供的通气性能测试装置的吸盘对第一排雾化器的轻压示 意图;
[0058] 图 14为本发明实施例提供的通气性能测试装置的吸盘组件测试通道中心孔与最
后一排雾化器的吸嘴中心孔对齐示意图;
[0059] 图 15为本发明实施例提供的通气性能测试装置的吸盘对最后一排雾化器的轻压 示意图。
本发明的实施方式
[0060] 本发明实施例通过提供一种电子烟雾化器通气性能测试装置, 解决了现有技术 中通过人工进行雾化器通气性能测试, 测试效率低, 测试吸力不稳定一致性差 的技术问题, 实现了在测试吋进行恒定抽气, 以形成恒定负压吸力同吋对多个 雾化器进行吸气测试, 使得测试吸力一致、 测试效率得到提高的技术效果。
[0061] 本发明实施例的技术方案为解决上述技术问题, 总体思路如下:
[0062] 本发明实施例提供了一种电子烟雾化器通气性能测试装置, 用于对排放在雾化 器承载板上的整板雾化器进行逐排自动测试, 所述通气性能测试装置包括: xyz 三轴平台, 真空发生系统和控制器; 所述 xyz三轴平台, 包括: 平台底座, 与所 述平台底座固定连接的测试梁, 滑动设置在所述平台底座上的 y轴移动板, 可移 动地设置在所述测试梁上的 X轴移动头, 设置在所述 X轴移动头上且可相对所述 X 轴移动头上下移动的 z轴移动头, 以及固定设置在所述 z轴移动头的端部且与所述 真空发生系统连通的吸盘组件; 所述控制器用于在进行雾化器通气性能测试吋 , 且排放有所述整板雾化器的雾化器承载板被固定在所述 y轴移动板上, 以及所 述 X轴移动头处于与测试工位对应的位置后, 启动并控制所述 y轴移动板和所述 z 轴移动头运动, 以使所述吸盘组件对准并轻压所述整板雾化器的至少一排雾化 器, 进而使所述真空发生系统对所述至少一排雾化器进行通气性能测试。
[0063] 可见, 在本发明实施例中, 电子烟雾化器通气性能测试装置包括: xyz三轴平 台, 真空发生系统和控制器; 进一步, 所述 xyz三轴平台包括: 平台底座、 X轴移 动头、 y轴移动板和 z轴移动头; 其中, 所述 X轴移动头、 所述 y轴移动板和所述 z 轴移动头可相对于所述平台底座运动。 在进行雾化器通气性能测试吋, 通过将 排放有整板雾化器的雾化器承载板固定放置在所述 y轴移动板上, 将用于在测试 吋连接雾化器的吸盘组件设置在所述 z轴移动头上 (其中, 所述吸盘组件还与产 生测试吸力的真空发生系统连通) , 且所述 X轴移动头处于与测试工位对应的位
置后, 所述控制器启动并控制所述 y轴移动板和所述 z轴移动头运动, 以使所述吸 盘组件对准并轻压所述整板雾化器的至少一排雾化器, 进而使所述真空发生系 统对所述至少一排雾化器进行通气性能测试。 也就是说, 在雾化器通气性能测 试吋, 通过结合 xyz三轴平台, 将吸盘组件同吋与多个待检测雾化器对准并紧密 连接, 使得真空发生系统通过气道和吸盘组件与电子烟雾化器进行连通, 可以 同吋检测多个电子烟雾化器的通气性能, 提高了测试效率, 并且真空发生系统 在测试吋进行恒定抽气, 以形成恒定负压吸力对连通的多个雾化器进行吸气测 试, 测试吸力一致, 适用于标准化生产。
[0064] 为了更好的理解上述技术方案, 下面将结合说明书附图以及具体的实施方式对 上述技术方案进行详细的说明, 应当理解本发明实施例以及实施例中的具体特 征是对本申请技术方案的详细的说明, 而不是对本申请技术方案的限定, 在不 冲突的情况下, 本发明实施例以及实施例中的技术特征可以相互组合。
[0065] 实施例一
[0066] 请参考图 1, 本发明实施例提供了一种电子烟雾化器通气性能测试装置, 用于 对排放在雾化器承载板 100上的整板雾化器 200进行逐排自动测试, 所述通气性 能测试装置包括: xyz三轴平台 1, 真空发生系统 2和控制器 3 ;
[0067] xyz三轴平台 1, 包括: 平台底座 11, 与平台底座 11固定连接的测试梁 12, 滑动 设置在平台底座 11上的 y轴移动板 111, 可移动地设置在测试梁 12上的 X轴移动头 121, 设置在 X轴移动头 121上且可相对 X轴移动头 121上下移动的 z轴移动头 122, 以及固定设置在 z轴移动头 122的端部且与真空发生系统 2连通的吸盘组件 123 ;
[0068] 控制器 3用于在进行雾化器通气性能测试吋, 且排放有整板雾化器 200的雾化器 承载板 100被固定在 y轴移动板 111上, 以及 X轴移动头 121处于与测试工位对应的 位置后, 启动并控制 y轴移动板 111和 z轴移动头 122运动, 以使吸盘组件 123对准 并轻压整板雾化器 200的至少一排雾化器, 进而使真空发生系统 2对所述至少一 排雾化器进行通气性能测试。
[0069] 在具体实施过程中, 当吸盘组件 123上设置的一排测试通道数大于或等于雾化 器承载板 100上一排雾化器的个数, 且 X轴移动头 121处于与所述测试工位对应的 位置吋, 控制器 3只需要控制 y轴移动板 111和 z轴移动头 122运动, 以使吸盘组件 1
23依次对承载板 100上的所有雾化器 200进行测试; 当吸盘组件 123上设置的一排 测试通道数小于雾化器承载板 100上一排雾化器的个数 (如雾化器承载板 100上 一排雾化器的个数为吸盘组件 123上设置的一排测试通道数的两倍) 吋, 控制器 3则需要控制 X轴移动头 121、 y轴移动板 111和 z轴移动头 122运动, 以使吸盘组件 1 23依次对承载板 100上的所有雾化器 200进行测试。
[0070] 进一步, 请结合图 1和图 2, 所述通气性能测试装置还包括: 设置在平台底座 11 内且分别与对应的 y轴移动板 111、 X轴移动头 121和 z轴移动头 122驱动连接的驱动 组件 4 (如气缸或电机等) , 驱动组件 4与控制器 3电连接; 控制器 3用于控制驱 动组件 4分别依次驱动 y轴移动板 111沿平台底座 11将整板雾化器 200移动至所述 测试工位, 驱动 X轴移动头 121沿测试梁 12移动至与所述测试工位对应的位置, 以及驱动 z轴移动头 122朝向所述测试工位上的整板雾化器 200运动, 以实现吸盘 组件 123对准并轻压整板雾化器 200的至少一排雾化器。
[0071] 具体的, 仍请参考图 2, 驱动组件 4包括与 y轴移动板 111驱动连接的第一驱动结 构 41, 与 X轴移动头 121驱动连接的第二驱动结构 42, 以及与 z轴移动头 122驱动连 接的第三驱动结构 43; 控制器 3分别与第一驱动结构 41、 第二驱动结构 42和第三 驱动结构 43连接, 控制器 3还用于在所述至少一排雾化器通气性能测试完成后, 控制 z轴移动头 122和 y轴移动板 111运动, 以使吸盘组件 123运动到与所述至少一 排雾化器相邻的再至少一排雾化器进行通气性能测试, 直至整板雾化器 200全部 测试完毕。
[0072] 进一步, 在具体实施过程中, 请参考图 3, 测试梁 12包括: 分别沿平台底座 11 一端部的两侧向上垂直延伸的两个垂直梁柱 124, 以及固定连接两个垂直梁柱 12 4顶端的与平台底座 11平行的水平梁柱 125; y轴移动板 111为一滑板, 在所述滑 板下方连接有第一驱动结构 41 ; X轴移动头 121呈倒 L型 (如图 1所示) , X轴移动 头 121—端与水平梁柱 125可移动连接, X轴移动头 121另一端朝向所述测试工位 延伸, 在水平梁柱 125中设置有第二驱动结构 42; z轴移动头 122设置在 X轴移动头 121的另一端上, z轴移动头 122的远离 X轴移动头 121的端部固定设置有吸盘组件 1 23, 在 X轴移动头 121中设置有第三驱动结构 43。 其中, 第一驱动结构 41、 第二 驱动结构 42或第三驱动结构 43均为气缸驱动结构或电机驱动结构等, 驱动技术
可采用现有比较成熟的技术, 这里不再一一赘述。 仍请参考图 3, 控制器 3设置 在平台底座 11内部, 包括控制器 3的控制电路 (图中未画出) , 为了方便操作人 员对通气性能测试装置进行操作, 在平台底座 11的表面设置有与控制器 3功能相 对应的多个控制按钮, 包括: 电源按钮 31、 第一驱动结构控制按钮 32、 第二驱 动结构控制按钮 33、 第三驱动结构控制按钮 34和真空发生系统幵关按钮 35等。
[0073] 接着, 请参考图 4, 吸盘组件 123包括多个测试通道 5; 吸盘组件 123的测试通道 数等于雾化器承载板 100上的所述至少一排雾化器的个数。 例如, 在具体实施过 程中, 雾化器承载板 100上设置有阵列排布的 10排 10列总共 100个用于放置雾化 器的凹槽, 用于摆放 100个雾化器, 吸盘组件 123上设置有与雾化器承载板 100上 一排雾化器对应的 10个测试通道; 在将装满雾化器的承载板 100放置到 y轴移动 板 111上, 且 X轴移动头 121处于与测试工位对应的位置后, 通过控制上述多个控 制按钮, 以控制 y轴移动板 111和 z轴移动头 122运动, 以使吸盘组件 123的 10个测 试通道对准并轻压雾化器承载板 100上的一排雾化器, 并启动真空发生系统 2对 该排雾化器抽气进行通气性能测试, 在所述该排测试完成后, 对下一排雾化器 进行通气性能测试, 直至雾化器承载板 100上的所有雾化器完成测试。
[0074] 进一步, 请参考图 4和图 5, 真空发生系统 2包括: 设置在测试梁 12上的多个真 空发生器 21 (如图 5所示) 和多个测试仪表 22 (如图 4所示) ; 其中, 多个真空 发生器 21中的任一真空发生器包括: 真空发生器调压阀 211 (仍如图 4所示) , 用于调节与所述任一真空发生器相连的连接气管中的负压值。 具体而言, 多个 真空发生器 21设置在所述通气性能测试装置的背面 (如图 5所示) , 在所述通气 性能测试装置的正面与多个真空发生器 21—一对应的位置上设置有多个真空发 生器调压阀 211 (如图 4所示) 。
[0075] 在具体实施过程中, 仍请参考图 4和图 5, 多个真空发生器 21的个数与所述测试 通道数相等, 且多个测试仪表 22的个数与所述测试通道数相等; 多个真空发生 器 21通过多条连接气管一一对应与多个测试通道 5连通; 多个真空发生器 21还通 过多条连接气管一一对应与多个测试仪表 22连通; 所有所述连接气管的长度均 满足 X轴移动头 121和 z轴移动头 122的运动行程需求, 其中, 所有所述连接气管可 采用软管, 优选地, 所述连接气管为能够弹性伸缩的波纹管; 在进行雾化器通
气性能测试的过程中, 多个真空发生器 21通过吸盘组件 123依次与整板雾化器 20 0的每一排的多个雾化器通气管一一对应相连通。 例如, 吸盘组件 123的测试通 道数为 10, 真空发生器 21的个数和测试仪表 22的个数也为 10, 且 10个真空发生 器 21—一对应与 10个测试通道 5和 10个测试仪表 22连通。
[0076] 进一步, 请参考图 6, 任一真空发生器 21还包括: 进气口 212、 出气口 213和抽 气口 214; 抽气口 214通过三通阀 215分别与多个测试通道 5中的一个测试通道和 多个测试仪表 22中的一个测试仪表连通。 图 6中, 箭头表示空气的流向, 具体的 , 压缩空气从进气口 212进入真空发生器 21, 从出气口 213喷出, 此过程在真空 发生器抽气口 214形成负压, 再经过三通阀 215分两路, 分别对测试仪表 22 (如 数显气压表) 和雾化器 200进行抽气。 可以通过测试仪表 22显示的负压差值变化 , 来判断雾化器 200的通气性能。 需要指出的是, 图 6为一路测试通道的工作原 理示意图, 对于多路测试通道的情况以此类推, 这里不再一一赘述。
[0077] 其中, 任一真空发生器 21的工作原理图如 7所示, 压缩空气经过气管由真空发 生器进气口 212进入真空发生器 21, 压缩空气进入扩散腔 216, 经过通气管道, 在出气口 213形成射流, 形成卷吸流动, 在卷吸流作用下, 吸附腔 217内的空气 经过单向阀 218不断被抽走形成一定真空度, 真空发生器抽气口 214形成负压。 通过调节调压阀 211左右移动, 减小或增大扩散腔 216与通气管道的通气量大小 即可调节抽气口 214处的负压大小。
[0078] 进一步, 请参考图 8, 吸盘组件 123包括: 多个导气管 51, 一一对应套设在多个 导气管 51上的多个吸盘转接头 52, 以及一一对应与多个导气管 51的下端密封连 接的多个吸盘 53; 在吸盘组件 123向整板雾化器 200的至少一排雾化器对准并轻 压的过程中, 多个吸盘 53用于吸附在所述至少一排雾化器的上端, 以使多个导 气管 51与所述至少一排雾化器通气孔一一对应连通; 图 8中箭头表示空气的流向 。 具体的, 依据如图 6和图 7所示的工作原理, 从每一真空发生器形成的负压, 经过与其连通的导气管 51、 吸盘转接头 52、 吸盘 53, 对该真空发生器所连通的 雾化器进行抽气, 检测该雾化器通气性能状况。
[0079] 在具体实施过程中, 由于雾化器承载板 100上用于放置雾化器 200的凹槽的深度 和 /或雾化器产品的长度存在设计误差, 而导致放置在雾化器承载板 100上的整板
雾化器 200中, 可能出现一排雾化器凸出承载板 100表面的管状部分的高度存在 不一致, 为了避免此高度不一致导致吸盘组件 123上的吸盘 53与雾化器吸嘴平面 之间存在不能压紧, 和 /或吸盘中心孔与雾化器通气孔不同心, 最终引起吸盘与 雾化器吸嘴之间气密性不佳的现象, 请参考图 9, 多个吸盘 53中的任一吸盘包括 褶皱缓冲结构 54; 在吸盘组件 123向整板雾化器 200的所述至少一排雾化器对准 并轻压吋, 褶皱缓冲结构 54被压附在被对准的雾化器的上端; 其中, 褶皱缓冲 结构 54为硅胶材质; 另外, 在具体实施过程中, 吸盘中心孔与雾化器通气孔同 心且孔径相同, 以提高测量的准确性。
[0080] 又由于在具体实施过程中, 进入每一真空发生器进气口 212的压缩空气来自外 部控压器, 其气压值比较大 (如 0.7bar) , 而雾化器通气性能测量所需要的气压 值为 0.3 (±0.05) bar, 为了在进气口 212对进入每一真空发生器 21的压缩空气进 行初步测控, 仍请参考图 4, 真空发生系统 2还包括: 多个气压测量表 23, 用于 分别测量并显示多个真空发生器 21的多个进气口 212的负压值; 与多个气压测量 表 23—一对应的多个气压调节阀 24, 用于调节多个进气口 212 (如图 6和图 7所示 ) 的负压值; 具体的, 在本申请实施例中, 多个测试仪表 22均采用数显气压表 , 每个气压测量表 23的测量量程大于数显气压表的测量量程; 并且, 多个气压 测量表 23的总个数小于或等于所述测试通道数 (即小于或等于所述多个数显气 压表的总个数) 。 例如, 在具体实施过程中, 采用的多个数显气压表的总个数 为两倍的多个气压测量表 23的总个数, 且所述通气性能测试装置具有 10个测试 通道, 即具有 10个真空发生器 21, 并且为这 10个真空发生器 21输入 5路压缩空气 , 其中, 输入的每路压缩空气分为两路分别通往两个真空发生器的进气口 212, 并且针对这 5路输入中的每一路分别对应设置一个气压测量表 23和气压调节阀 24 , 以对这 5路输入的压缩空气的压力进行初步测控, 进一步, 后续测量中, 则通 过多个测试仪表 22对每一个真空发生器的连通管道中的负压值进行微调; 当然 , 多个气压测量表 23的总个数还可等于多个测试仪表 22的总个数, 在这种情况 下, 10个真空发生器 21输入 10路压缩空气, 输入的 10路压缩空气分别一一对应 通往 10个真空发生器的进气口 212。
[0081] 在具体实施过程中, 多个测试仪表 22均为数显气压表, 在所述数显气压表中预
设有雾化器通气性能气压阈值, 如 (-0.3±0.05) bar, 所述数显气压表包括: 报 警单元, 用于在测量获得的负压值超过所述气压阈值吋进行报警; 例如, 在某 一数显气压表测得管道中的负压值为 -0.36 bar吋, 该数显气压表所显示的数值颜 色将变色 (如由黑色变为红色) , 并且发出音频报警信号。
[0082] 总而言之, 在本申请方案中, 通过真空发生系统产生测试所需的吸力, 实现以 恒定抽气形成恒定负压吸力, 并以此恒定负压吸力对雾化器和对应的数显气压 表同吋进行吸气, 通过数显气压表显示气压差值, 以反映所测试的雾化器的通 气性能; 进一步, 通过这种检测方式, 利用真空发生系统产生批量且一致的测 试吸力, 再结合 xyz三轴平台, 使得测试过程中真空发生系统中的真空发生器通 过气道和吸盘与电子烟或其雾化器进行紧密连接, 同吋检测多个电子烟雾化器 的通气性能, 提高了测试效率, 并且真空发生系统在测试吋进行恒定抽气, 以 形成恒定负压吸力对连通的多个雾化器进行吸气测试, 测试吸力一致, 可适用 于标准化生产; 另外, 所述吸盘设有褶皱缓冲结构, 有效地避免吸盘与雾化器 吸嘴平面不能压紧, 吸盘抽气孔小于雾化器靠近吸盘的端面, 而引起吸盘与雾 化器吸嘴之间气密性不佳、 测量不准确的现象; 通过采用抽气孔孔径与雾化器 通气孔孔径相同的吸盘, 以提高测量的准确性。
[0083] 实施例二
[0084] 基于同一发明构思, 请参考图 10, 本发明实施例还提供了一种电子烟雾化器通 气性能测试方法, 应用于如实施例一所述的电子烟雾化器通气性能测试装置中 , 所述通气性能测试装置包括 xyz三轴平台 1、 真空发生系统 2和控制器 3 ; xyz三 轴平台 1包括 X轴移动头 121、 y轴移动板 111、 z轴移动头 122和吸盘组件 123 ; 排放 有整板雾化器 200的雾化器承载板 100固定在 y轴移动板 111上, 且 x轴移动头 121 处于与测试工位对应的位置, 所述方法包括步骤:
[0085] Sl、 当接收到进行雾化器通气性能测试的启动指令吋, 控制所述 y轴移动板 11 1和所述 z轴移动头 122运动, 以使所述吸盘组件 123对准并轻压所述整板雾化器 20 0的至少一排雾化器;
[0086] S2、 启动所述真空发生系统 2对所述至少一排雾化器进行通气性能测试;
[0087] S3、 在所述至少一排雾化器通气性能测试完成后, 控制所述 z轴移动头 122和所
述 y轴移动板 111运动, 以使所述吸盘组件 123运动到与所述至少一排雾化器相邻 的再至少一排雾化器进行通气性能测试, 直至所述整板雾化器 200全部测试完毕
[0088] 在具体实施过程中, 雾化器承载板 100上设置有阵列排布的 10排 10列总共 100个 用于放置雾化器的凹槽, 用于放置 100个雾化器, 吸盘组件 123上设置有与雾化 器承载板 100上一排雾化器对应的 10个测试通道, 所述通气性能测试装置的 xyz三 轴平台 1位于初始状态 (如图 11所示) : z轴移动头 122收缩于 X轴移动头 121的一 端中, X轴移动头 121位于所述通气性能测试装置的水平梁柱 125的左端 1251, y 轴移动板 111位于所述通气性能测试装置的平台底座 11的最末端 112。 下面对上 述步骤 S1~S3进行详细描述:
[0089] 在将装满雾化器的承载板放置到 y轴移动板 111上, 并通过控制上述多个控制按 钮, 控制 X轴移动头 121带动 z轴移动头 122向水平梁柱 125的右端移动, 以及控制 y 轴移动板 111带动放置有 100个雾化器的雾化器承载板 100向与最末端 112相反的 方向移动, 以使吸盘组件 123的 10个吸盘中心孔与第一排雾化器的吸嘴的中心孔 对齐 (如图 12所示) ; 接着, 控制 z轴移动头 122向下移动 (如图 13所示中箭头所 示方向) 至吸盘组件 123的吸盘一一对应轻压第一排雾化器, 进行通气性能测试 ; 进一步, 如图 14所示, 控制 z轴移动头 122向上运动, 并控制 y轴移动板 111带动 整板雾化器 200继续向与最末端 112相反的方向移动, 以使吸盘组件 123的 10个吸 盘中心孔与第二排雾化器的吸嘴的中心孔对齐; 接着, 再次控制 z轴移动头 122向 下移动至吸盘组件 123的吸盘一一对应轻压第二排雾化器, 进行通气性能测试, 依此类推, 直至 100个雾化器的最后一排雾化器测试完毕 (如图 15所示) ; 进一 步, 如图 11中箭头所示, X轴移动头 121、 y轴移动板 111和 z轴移动头 122分别归位 , 以使所述通气性能测试装置的 xyz三轴平台 1归于初始状态。
[0090] 当然, 在具体实施过程中, 根据应用需要, 所述通气性能测试装置的测试通道 数也可设置为 20个、 30个等, 雾化器承载板 100上可设置能够排放更多雾化器的 凹槽, 如 200个、 300个等, 对此这里不做具体限定。
[0091] 本领域内的技术人员应明白, 本发明的实施例可提供为方法、 系统、 或计算机 程序产品。 因此, 本发明可采用完全硬件实施例、 完全软件实施例、 或结合软
件和硬件方面的实施例的形式。 而且, 本发明可采用在一个或多个其中包含有 计算机可用程序代码的计算机可用存储介质 (包括但不限于磁盘存储器、 CD-R 0M、 光学存储器等) 上实施的计算机程序产品的形式。
[0092] 这些计算机程序指令也可装载到计算机或其他可编程数据处理设备上, 使得在 计算机或其他可编程设备上执行一系列操作步骤以产生计算机实现的处理, 从 而在计算机或其他可编程设备上执行的指令提供用于实现在流程图一个流程或 多个流程和 /或方框图一个方框或多个方框中指定的功能的步骤。
[0093] 尽管已描述了本发明的优选实施例, 但本领域内的技术人员一旦得知了基本创 造性概念, 则可对这些实施例做出另外的变更和修改。 所以, 所附权利要求意 欲解释为包括优选实施例以及落入本发明范围的所有变更和修改。
[0094] 显然, 本领域的技术人员可以对本发明进行各种改动和变型而不脱离本发明的 精神和范围。 这样, 倘若本发明的这些修改和变型属于本发明权利要求及其等 同技术的范围之内, 则本发明也意图包含这些改动和变型在内。
Claims
权利要求书
[权利要求 1] 一种电子烟雾化器通气性能测试装置, 用于对排放在雾化器承载 板 (100) 上的整板雾化器 (200) 进行逐排自动测试, 其特征在 于, 所述通气性能测试装置包括: xyz三轴平台 (1) , 真空发生 系统 (2) 和控制器 (3) ;
所述 xyz三轴平台 (1) , 包括: 平台底座 (11) , 与所述平台底 座 (11) 固定连接的测试梁 (12) , 滑动设置在所述平台底座 (1 1) 上的 y轴移动板 (111) , 可移动地设置在所述测试梁 (12) 上 的 X轴移动头 (121) , 设置在所述 X轴移动头 (121) 上且可相对 所述 X轴移动头 (121) 上下移动的 z轴移动头 (122) , 以及固定 设置在所述 z轴移动头 (122) 的端部且与所述真空发生系统 (2) 连通的吸盘组件 (123) ;
所述控制器 (3) 用于在进行雾化器通气性能测试吋, 且排放有所 述整板雾化器 (200) 的雾化器承载板 (100) 被固定在所述 y轴移 动板 (111) 上, 以及所述 X轴移动头 (121) 处于与测试工位对应 的位置后, 启动并控制所述 y轴移动板 (111) 和所述 z轴移动头 ( 122) 运动, 以使所述吸盘组件 (123) 对准并轻压所述整板雾化 器 (200) 的至少一排雾化器, 进而使所述真空发生系统 (2) 对 所述至少一排雾化器进行通气性能测试。
[权利要求 2] 如权利要求 1所述的通气性能测试装置, 其特征在于, 所述通气性 能测试装置还包括: 设置在所述平台底座 (11) 内且分别与对应 的所述 y轴移动板 (111) 、 所述 X轴移动头 (121) 和所述 z轴移动 头 (122) 驱动连接的驱动组件 (4) , 所述驱动组件 (4) 与所述 控制器 (3) 电连接; 所述控制器 (3) 用于控制所述驱动组件 (4 ) 分别依次驱动所述 y轴移动板 (111) 沿所述平台底座 (11) 将 所述整板雾化器 (200) 移动至所述测试工位, 驱动所述 X轴移动 头 (121) 沿所述测试梁 (12) 移动至与所述测试工位对应的位置 , 以及驱动所述 z轴移动头 (122) 朝向所述测试工位上的整板雾
化器 (200) 运动, 以实现所述吸盘组件 (123) 对准并轻压所述 整板雾化器 (200) 的至少一排雾化器。
[权利要求 3] 如权利要求 2所述的通气性能测试装置, 其特征在于, 所述驱动组 件 (4) 包括与所述 y轴移动板 (111) 驱动连接的第一驱动结构 ( 41) , 与所述 X轴移动头 (121) 驱动连接的第二驱动结构 (42) , 以及与所述 z轴移动头 (122) 驱动连接的第三驱动结构 (43) 所述控制器 (3) 分别与所述第一驱动结构 (41) 、 所述第二驱动 结构 (42) 和所述第三驱动结构 (43) 连接, 所述控制器 (3) 还 用于在所述至少一排雾化器通气性能通气性能测试完成后, 控制 所述 z轴移动头 (122) 和所述 y轴移动板 (111) 运动, 以使所述 吸盘组件 (123) 运动到与所述至少一排雾化器相邻的再至少一排 雾化器进行通气性能测试, 直至所述整板雾化器 (200) 全部测试 完毕。
[权利要求 4] 如权利要求 3所述的通气性能测试装置, 其特征在于, 所述测试梁
(12) 包括: 分别沿所述平台底座 (11) 一端部的两侧向上垂直 延伸的两个垂直梁柱 (124) , 以及固定连接所述两个垂直梁柱 ( 124) 顶端的与所述平台底座 (11) 平行的水平梁柱 (125) ; 所述 y轴移动板 (111) 为一滑板, 在所述滑板下方连接有所述第 一驱动结构 (41) ;
所述 X轴移动头 (121) 呈倒 L型, 所述 X轴移动头 (121) —端与所 述水平梁柱 (125) 可移动连接, 所述 X轴移动头 (121) 另一端朝 向所述测试工位延伸, 在所述水平梁柱 (125) 中设置有所述第二 驱动结构 (42) ;
所述 z轴移动头 (122) 设置在所述 X轴移动头 (121) 的另一端上 , 所述 z轴移动头 (122) 的远离所述 X轴移动头 (121) 的端部固 定设置有所述吸盘组件 (123) , 在所述 X轴移动头 (121) 中设置 有所述第三驱动结构 (43) 。
[权利要求 5] 如权利要求 1所述的通气性能测试装置, 其特征在于, 所述吸盘组 件 (123) 包括多个测试通道 (5) ;
所述吸盘组件 (123) 的测试通道数等于所述雾化器承载板 (100 ) 上的所述至少一排雾化器的个数。
[权利要求 6] 如权利要求 5所述的通气性能测试装置, 其特征在于, 所述真空发 生系统 (2) 包括: 设置在所述测试梁 (12) 上的多个真空发生器
(21) 和多个测试仪表 (22) ; 所述多个真空发生器 (21) 的个 数与所述测试通道数相等, 且所述多个测试仪表 (22) 的个数与 所述测试通道数相等;
所述多个真空发生器 (21) 通过多条连接气管一一对应与所述多 个测试通道 (5) 连通; 所述多个真空发生器 (21) 还通过多条连 接气管一一对应与所述多个测试仪表 (22) 连通;
在进行雾化器通气性能测试的过程中, 所述多个真空发生器 (21 ) 通过所述吸盘组件 (123) 依次与所述整板雾化器 (200) 的每 一排的多个雾化器通气管一一对应相连通。
[权利要求 7] 如权利要求 6所述的通气性能测试装置, 其特征在于, 所述多个测 试仪表 (22) 均为数显气压表。
[权利要求 8] 如权利要求 7所述的通气性能测试装置, 其特征在于, 在所述数显 气压表中预设有雾化器通气性能气压阈值, 所述数显气压表包括 报警单元, 用于在测量获得的负压值超过所述气压阈值吋进行报
[权利要求 9] 如权利要求 6所述的通气性能测试装置, 其特征在于, 所有所述连 接气管为能够弹性伸缩的波纹管, 以使所述连接气管的长度均满 足所述 X轴移动头 (121) 和所述 z轴移动头 (122) 的运动行程需 求。
[权利要求 10] 如权利要求 6所述的通气性能测试装置, 其特征在于, 所述多个真 空发生器 (21) 中的任一真空发生器包括:
真空发生器调压阀 (211) , 用于调节与所述任一真空发生器相连 的连接气管中的负压值。
[权利要求 11] 如权利要求 10所述的通气性能测试装置, 其特征在于, 所述任一 真空发生器还包括: 进气口 (212) 、 出气口 (213) 和抽气口 (2 所述抽气口 (214) 通过三通阀 (215) 分别与所述多个测试通道
(5) 中的一个测试通道和所述多个测试仪表 (22) 中的一个测试 仪表连通。
[权利要求 12] 如权利要求 11所述的通气性能测试装置, 其特征在于, 所述真空 发生系统 (2) 还包括:
多个气压测量表 (23) , 用于分别测量并显示所述多个真空发生 器 (21) 的多个进气口 (212) 的负压值;
与所述多个气压测量表 (23) —一对应的多个气压调节阀 (24)
, 用于调节所述多个进气口 (212) 的负压值;
其中, 所述多个气压测量表 (23) 的个数小于或等于所述测试通 道数。
[权利要求 13] 如权利要求 1所述的通气性能测试装置, 其特征在于, 所述吸盘组 件 (123) 包括: 多个导气管 (51) , 一一对应套设在所述多个导 气管 (51) 上的多个吸盘转接头 (52) , 以及一一对应与所述多 个导气管 (51) 的下端密封连接的多个吸盘 (53) ;
在所述吸盘组件 (123) 向所述整板雾化器 (200) 的至少一排雾 化器对准并轻压的过程中, 所述多个吸盘 (53) 用于吸附在所述 至少一排雾化器的上端, 以使所述多个导气管 (51) 与所述至少 一排雾化器通气孔一一对应连通。
[权利要求 14] 如权利要求 13所述的通气性能测试装置, 其特征在于, 所述多个 吸盘 (53) 中的任一吸盘包括褶皱缓冲结构 (54) ;
在所述吸盘组件 (123) 向所述整板雾化器 (200) 的所述至少一 排雾化器对准并轻压吋, 所述褶皱缓冲结构 (54) 被压附在被对
准的雾化器的上端。
[权利要求 15] 如权利要求 14所述的通气性能测试装置, 其特征在于, 所述褶皱 缓冲结构 (54) 为硅胶材质。
[权利要求 16] —种电子烟雾化器通气性能测试方法, 应用于电子烟雾化器通气 性能测试装置中, 其特征在于, 所述通气性能测试装置包括 xyz三 轴平台 (1) 、 真空发生系统 (2) 和控制器 (3) ; 所述 xyz三轴 平台 (1) 包括 X轴移动头 (121) 、 y轴移动板 (111) 、 z轴移动 头 (122) 和吸盘组件 (123) ; 排放有整板雾化器 (200) 的雾化 器承载板 (100) 固定在所述 y轴移动板 (111) 上, 且所述 X轴移 动头 (121) 处于与测试工位对应的位置, 所述方法包括步骤:
51、 当接收到进行雾化器通气性能测试的启动指令吋, 控制所述 y 轴移动板 (111) 和所述 z轴移动头 (122) 运动, 以使所述吸盘组 件 (123) 对准并轻压所述整板雾化器 (200) 的至少一排雾化器
52、 启动所述真空发生系统 (2) 对所述至少一排雾化器进行通气 性能通气性能测试;
53、 在所述至少一排雾化器通气性能通气性能测试完成后, 控制 所述 z轴移动头 (122) 和所述 y轴移动板 (111) 运动, 以使所述 吸盘组件 (123) 运动到与所述至少一排雾化器相邻的再至少一排 雾化器进行通气性能测试, 直至所述整板雾化器 (200) 全部测试 完毕。
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CN108120562A (zh) * | 2017-12-28 | 2018-06-05 | 乐清市秋瑞软件开发有限公司 | 一种传感器检测装置 |
USD825102S1 (en) | 2016-07-28 | 2018-08-07 | Juul Labs, Inc. | Vaporizer device with cartridge |
US10045568B2 (en) | 2013-12-23 | 2018-08-14 | Juul Labs, Inc. | Vaporization device systems and methods |
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US10244793B2 (en) | 2005-07-19 | 2019-04-02 | Juul Labs, Inc. | Devices for vaporization of a substance |
US10279934B2 (en) | 2013-03-15 | 2019-05-07 | Juul Labs, Inc. | Fillable vaporizer cartridge and method of filling |
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USD851830S1 (en) | 2016-06-23 | 2019-06-18 | Pax Labs, Inc. | Combined vaporizer tamp and pick tool |
US10405582B2 (en) | 2016-03-10 | 2019-09-10 | Pax Labs, Inc. | Vaporization device with lip sensing |
US10512282B2 (en) | 2014-12-05 | 2019-12-24 | Juul Labs, Inc. | Calibrated dose control |
USD887632S1 (en) | 2017-09-14 | 2020-06-16 | Pax Labs, Inc. | Vaporizer cartridge |
US10865001B2 (en) | 2016-02-11 | 2020-12-15 | Juul Labs, Inc. | Fillable vaporizer cartridge and method of filling |
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US10667560B2 (en) | 2013-12-23 | 2020-06-02 | Juul Labs, Inc. | Vaporizer apparatus |
US10058124B2 (en) | 2013-12-23 | 2018-08-28 | Juul Labs, Inc. | Vaporization device systems and methods |
US10058130B2 (en) | 2013-12-23 | 2018-08-28 | Juul Labs, Inc. | Cartridge for use with a vaporizer device |
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US10865001B2 (en) | 2016-02-11 | 2020-12-15 | Juul Labs, Inc. | Fillable vaporizer cartridge and method of filling |
US10405582B2 (en) | 2016-03-10 | 2019-09-10 | Pax Labs, Inc. | Vaporization device with lip sensing |
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USD836541S1 (en) | 2016-06-23 | 2018-12-25 | Pax Labs, Inc. | Charging device |
USD851830S1 (en) | 2016-06-23 | 2019-06-18 | Pax Labs, Inc. | Combined vaporizer tamp and pick tool |
USD842536S1 (en) | 2016-07-28 | 2019-03-05 | Juul Labs, Inc. | Vaporizer cartridge |
USD825102S1 (en) | 2016-07-28 | 2018-08-07 | Juul Labs, Inc. | Vaporizer device with cartridge |
USD887632S1 (en) | 2017-09-14 | 2020-06-16 | Pax Labs, Inc. | Vaporizer cartridge |
CN108120562A (zh) * | 2017-12-28 | 2018-06-05 | 乐清市秋瑞软件开发有限公司 | 一种传感器检测装置 |
US12082618B2 (en) | 2018-12-31 | 2024-09-10 | Juul Labs, Inc. | Cartridges for vaporizer devices |
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