Emulation Aerosol Sucker
`
`TECHNICAL FIELD
`
`relates to an electronic suction apparatus,
`This utility model
`emulation aerosol sucker that doesn't contain tar but nicotine.
`
`in particular, an
`
`BACKGROUND ART
`
`10
`
`15
`
`20
`
`25
`
`30
`
`35
`
`Today when "smoking is harmful to your health" has become a common sense, there
`
`are one billion people smoking cigarettes, and this figure is still rising. On Mar. 1,
`
`2003, the World Health Organization (WHO) issued the first international smoking
`ban-Framework Convention on Tobacco Control. According to WHO'S data, smoking
`
`causes 4,900,000 deaths each year. Smoking causes serious respiratory system
`
`diseases and cancers, though it is a hard job to persuade the smokers to completely
`
`quit smoking.
`
`Nicotine is the effective ingredient of cigarette, which produces a lot of tar mist as the
`
`cigarette burns. The tar mist accesses the pulmonary alveolus and is quickly absorbed
`
`into the blood. Nicotine thus acts on the receptor of the central nervous system,
`
`bringing the euphoria like stimulant drugs to the smokers, who feel light in the head
`
`and on wings as well.
`
`Nicotine is a micromolecular alkaloid, which is basically harmless to human bodies
`
`with a small dosage. Plus, its half life period is extremely short in blood. Tar is the
`
`major harmful substance in tobacco. Tobacco tar comprises of several thousands of
`
`ingredients, dozens of which are carcinogenic substances. It has now been proved that
`
`second hand smoking is even more harmful to those who don't smoke.
`
`To seek the cigarette substitutes that don't contain harmful tar but nicotine, many
`
`inventors have used the relatively pure nicotine to create such products as "Cigarette
`
`Patch", "Nicotine Gargle", "Aerosol Packed in the High Pressure Tank with
`
`Propellant", "Nicotine Chewing Gum", and "Nicotine Beverage". These products are
`
`not as harmful as tar, but are absorbed very slowly. As a result, its peak concentration
`
`can't be effectively established in blood, and the smokers can't be satisfied to the full.
`
`In addition,
`
`the smokers are deprived of the "smoking" habit. Therefore,
`
`the
`
`substituting products are not real cigarette substitutes or products helping to quit
`
`smoking.
`
`40
`
`CONTENTS OF THE UTILITY MODEL
`
`The purpose of this utility model
`
`is to provide an emulation aerosol sucker that
`
`substitutes for cigarettes and helps the smokers to quit smoking.
`
`1
`
`R.J. Reynolds Vapor
`IPR2016-01532
`
`R.J. Reynolds Vapor v. Fontem
`Exhibit 1004-00001
`
`

`
`The technical solution of this utility model is the further innovation of the utility
`
`model called "Aerosol Electronic Cigarette" for which the inventor filed with the
`
`State Intellectual Property Office of the People's Republic of China on Apr. 14, 2000,
`
`with the application number of 2004003ll82.0, and the international application
`number of PCT/CN2005/000337.
`
`The purpose of this utility model is fulfilled with the following solution: this utility
`
`model
`
`includes a battery assembly, an atomizer assembly and a cigarette bottle
`
`assembly; an external thread electrode is located in one end of the battery assembly,
`
`and an internal thread electrode is located in one end of the atomizer assembly; the
`
`battery assembly and the atomizer assembly are connected through the thread
`
`electrodes, and the cigarette bottle assembly is inserted into the other end of the
`
`atomizer assembly, thus forming one cigarette type or cigar type body.
`
`Therein, the battery assembly includes indicators, a lithium battery, a MOSFTET
`
`electric circuit board, a sensor, a silicon rubber corrugated membrane, a first thread
`
`electrode, a first negative pressure cavity, and a first shell. On one end of the first shell
`
`is the external thread electrode, while on the other end is the indicators. On one side
`
`of the first shell is an indicator cap, in which there is a fine hole. On the other side of
`
`the first shell,
`
`the lithium battery and the MOSFET electric circuit board are
`
`connected successively. The sensor is located on MOSFET electric circuit board.
`
`Between the first thread electrode and the sensor is the silicon rubber corrugated
`
`membrane, on which there is the first negative pressure cavity. The sensor is
`
`connected with the silicon rubber corrugated membrane through the reed switch fixed
`
`thereon. MCU is provided between the MOSFET electric circuit board and the sensor.
`
`On the surface of the first shell, a screen is provided. The MCU scans the sensor in the
`
`power-saving mode of pulse, and according to the signal parameters of the sensor,
`
`restricts the atomizing capacity with the integral function of frequency to single
`
`operation time. Also, the MCU accomplishes the following controls: the pulse width
`
`modulation and over discharging protection for the constant power output of the
`
`electric current; automatic cleaning function for thousands of times per operation; step
`
`lighting/dying down control of the indicators; display of the operation times and
`
`battery capacity; and automatic recovery after sensor malfunction shutdown, etc. The
`
`sensor may be switch sensor made of elastic alloy slice, Hall element of linear output,
`
`semiconductor force-sensitive chip, semiconductor matrix thermoelectric bridge chip,
`
`or capacitance and inductance sensor. The indicators are two red LEDS. The silicon
`
`rubber corrugated membrane may be made of fluorinated rubber, butyronitrile rubber,
`
`or elastic alloy film. The external thread electrode is a gold-coated stainless steel or
`
`brass part with a hole drilled in the center. The lithium battery may be either a
`
`rechargeable polymer lithium battery or a rechargeable lithium ion battery. The
`
`atomizer assembly includes the internal thread electrode, an air-liquid separator, an
`atomizer and the second shell. One end of the second shell
`is inserted into the
`
`cigarette bottle assembly for connection, while the other end of the second shell has
`
`the internal thread electrode, in which there is the second negative pressure cavity.
`
`2
`
`10
`
`15
`
`20
`
`25
`
`30
`
`35
`
`40
`
`Exhibit 1004-00002
`
`

`
`The air-liquid separator and the atomizer are connected with the internal thread
`
`electrode successively. On the second shell, there is an air intake channel. The internal
`
`thread electrode is a gold-coated stainless steel or brass part with a hole drilled in the
`
`center. The air—liquid separator is made of stainless steel or plastic with a hole drilled.
`
`The atomizer may be a capillary impregnation atomizer or a spray atomizer, inside
`
`which there is a heating body. The spray atomizer has a spray hole on it. The spray
`
`hole is made through molding and drilling foamed ceramics, micro-porous ceramics,
`
`foamed metal, stainless steel fiber felt, or chemical fiber. The heating body is made of
`
`a micro-porous ceramics holder on which electric heating materials,
`
`such as
`
`nickel-chromium alloy wire, iron-chromium alloy wire, or platinum wire, are wound.
`
`Alternatively, heating body may be a porous component made of electrically
`
`conductive ceramics or PTC ceramics, with a sintered electrode. The surface of the
`
`heating body is sintered into high-temperature glaze to fix the zeolite grains, which
`
`are made of natural zeolite, artificial non—organic micro-porous ceramics or aluminum
`
`oxide grains. The cigarette bottle assembly includes a cigarette liquid bottle, fiber and
`
`a suction nozzle. The fiber containing cigarette liquid is located on one end of the
`
`cigarette liquid bottle, and this end is inserted into the second shell and lies against the
`
`atomizer. The suction nozzle is located on the other end of the cigarette liquid bottle.
`
`Between the fiber and interior wall of the cigarette liquid bottle is an air suction
`
`channel. The cigarette liquid bottle and the suction nozzle are made of non-toxic
`
`plastic. The fiber is made of polypropylene fiber or nylon fiber. The cigarette liquid in
`the fiber for atomization contains 0.1-3.5% of nicotine, 0.05-5% of tobacco flavor,
`
`0.1-3% of organic acid, 0. l—O.5% of stabilizer, and propanediol for the remaining. The
`
`said sucker and its connecting structure may be taken as a drug delivery device of
`
`pulmonary suction with routine medicines loaded.
`
`This invention will bring the following benefits and active effects: For this utility
`
`model,
`
`smoking doesn't bring any cigarette tar, considerably reducing the
`
`carcinogenic risks. At
`
`the same time,
`
`the smokers can still enjoy the feel and
`
`excitement of smoking, and there is no fire hazard since there is no need for igniting.
`
`In addition, the apparatus and its connecting structure of this utility model may be
`
`loaded with conventional drugs for delivery to the lung.
`
`DESCRIPTION OF DRAWINGS
`
`FIG. 1 is the diagram of visual appearance of the cigarette type of this utility model.
`
`FIG. 2A is the diagram of one structure of the battery assembly of this utility model.
`
`FIG. 2B is the diagram of another structure of the battery assembly of this utility
`model.
`
`FIG. 3 is the diagram of the atomizer assembly of this utility model.
`
`10
`
`15
`
`20
`
`25
`
`30
`
`35
`
`40
`
`Exhibit 1004-00003
`
`

`
`FIG. 4 is the diagram of the cigarette bottle assembly of this utility model.
`
`FIG. 5A is the diagram of one internal structure of this utility model.
`
`FIG. 5B is the diagram of another internal structure of this utility model.
`
`FIG. 6 is the diagram of the structure of the charger of this utility model.
`
`10
`
`15
`
`20
`
`25
`
`30
`
`35
`
`FIG. 7 is the electric circuit diagram of MCU and MOSFET of this utility model.
`
`FIG. 8 is the diagram of the structure of the capillary impregnation atomizer of this
`
`utility model.
`
`FIG. 9 is the left view of FIG. 8.
`
`FIG. 10 is the diagram of the structure of the spray atomizer of this utility model.
`
`FIG. 11 is the left view of FIG. 10.
`
`FIG. 12 is the diagram of the structure of the cigar type contour of this utility model.
`
`SPECIFIC MODE FOR CARRYING OUT THE UTILITY MODEL
`
`This utility model is further described as follows on the basis of the drawings.
`
`Example 1
`
`As shown in FIG. 1, the visual appearance of this utility model is similar to a cigarette
`
`inserted into the cigarette holder. The emulation aerosol sucker includes a battery
`
`assembly, an atomizer assembly and a cigarette bottle assembly. An external thread
`
`electrode 209 is located in one end of the battery assembly, and an internal thread
`
`electrode 302 is located in one end of the atomizer assembly. The battery assembly
`
`and atomizer assembly are connected through the thread electrodes into an emulation
`
`cigarette. The cigarette bottle assembly is inserted into the other end of atomizer
`
`assembly, to form one cigarette type emulation aerosol sucker.
`
`As shown in FIG. 2A, the battery assembly includes indicators 202, a lithium battery
`
`203, a MOSFTET electric circuit board 205, a sensor 207, a silicone rubber
`
`40
`
`corrugated membrane 208, a first thread electrode 209, a first negative pressure cavity
`210, and a first shell 211. On one end of the first shell 211 is the external thread
`
`electrode 209, while on the other end are the indicators 202. On one side of the shell
`
`211, an indicator cap 201 is provided, in which there is a fine hole 501. On the other
`
`side of the shell 211, the lithium battery 203 and the MOSFET (Metallic Oxide
`
`Semiconductor Field Effect Tube) electric circuit board 205 are connected
`
`4
`
`Exhibit 1004-00004
`
`

`
`successively. The sensor 207 is located on the MOSFET electric circuit board 205.
`Between the first thread electrode 209 and the sensor 207 is the silicon rubber
`
`corrugated membrane 208, on which there is the first negative pressure cavity 210.
`
`The sensor 207 is connected with the silicon rubber corrugated membrane 208
`
`through the reed switch 212 fixed thereon.
`
`Therein, the sensor 207 may be switch sensor made of elastic alloy slice, Hall element
`
`of
`
`linear
`
`output,
`
`semiconductor
`
`force—sensitive
`
`chip,
`
`semiconductor matrix
`
`thermoelectric bridge chip, or capacitance and inductance sensor. The indicators 202
`
`are two red LEDs. The lithium battery 203 may be either a rechargeable polymer
`
`lithium battery or a rechargeable lithium ion battery. The external thread electrode 209
`
`is a gold-coated stainless steel or brass part with a hole drilled in the center. The
`
`silicon rubber corrugated membrane 208 may alternatively be made of fluorinated
`
`rubber, butyronitrile rubber, or elastic alloy film.
`
`As shown in FIG. 3, the atomizer assembly includes an internal thread electrode 302,
`
`an air-liquid separator 303, an atomizer 307 and a second shell 306. One end of the
`
`second shell 306 is inserted into the cigarette bottle assembly for connection, while
`
`the other end has the internal thread electrode 302, in which there is a second negative
`
`pressure cavity 301. The air-liquid separator 303 and the atomizer 307 are connected
`
`with the internal thread electrode 302 successively. On the second shell 306, there is
`
`an air intake channel 502. The air-liquid separator 303 is made of stainless steel or
`
`plastic with a hole drilled. The internal thread electrode 302 is a gold-coated stainless
`
`steel or brass part with a hole drilled in the center.
`
`The atomizer 307 may be a capillary impregnation atomizer as FIGS. 8 and 9 show, or
`
`a spray atomizer as FIGS. 10 and 11 show. For this embodiment, it is a spray atomizer.
`
`As shown in FIG. 4, the cigarette bottle assembly includes a cigarette liquid bottle 401,
`
`fiber 402 and a suction nozzle 403. The fiber 402 containing cigarette liquid is located
`
`on one end of the cigarette liquid bottle 401, and this end is inserted into the second
`
`shell 306 and lies against the atomizer 307. The suction nozzle 403 is located on the
`
`other end of the cigarette liquid bottle 401. Between the fiber 402 and interior wall of
`
`the cigarette liquid bottle 401 is an air suction channel 503.
`
`As shown in FIG. 5A, the standby state of this utility model has the fully charged
`
`battery assembly shown in FIG. 2A fastened onto the atomizer assembly shown in
`
`FIG. 3, which is then inserted into the cigarette bottle assembly shown in FIG. 4.
`
`When the user slightly sucks the suction nozzle 403 with mouth, the negative pressure
`
`is formed on the silicon rubber corrugated membrane 208 through the air suction
`
`channel 503 and the first and second negative pressure cavities 210, 301. The silicon
`
`rubber corrugated membrane 208, under" the action of suction pressure difference,
`
`thereby starting the
`deforms to drive the reed switch 212 and the sensor 207,
`MOSFET electric circuit board 205. At this moment,
`the indicators 202 are lit
`
`5
`
`10
`
`15
`
`20
`
`25
`
`30
`
`35
`
`40
`
`Exhibit 1004-00005
`
`

`
`gradually; the lithium battery 203 electrifies a heating body 305 inside the atomizer
`
`307 through the MOSFET electric circuit board 205 as well as the internal and
`
`external thread electrodes 302, 209, so that the heating body 305 inside the atomizer
`
`307 produces heat. The fiber 402 inside the cigarette liquid bottle 401 contains
`
`cigarette liquid, which soaks a micro-porous ceramics 801 inside the atomizer through
`
`the fiber 402. The air enters through the air intake hole 502, passes through the
`
`run-through hole on the air-liquid separator 303, and helps to form air-liquid mixture
`
`in a spray nozzle 304 of the atomizer 307. The air-liquid mixture sprays onto the
`
`heating body 305, gets vaporized, and is quickly absorbed into the airflow and
`
`condensed into aerosol, which passes through the air suction channel503 and is
`
`sucked out by suction nozzle 403 to form white mist type aerosol.
`
`When suction stops, the reed switch 212 and the sensor 207 are reset; the atomizer
`
`307 stops working; the indicators 202 gradually die down. When the operation times
`
`reaches the pre-set value, the atomizer 307 provides a work delay of 5-20 seconds per
`
`time, so as to remove the micro-dirt accumulated on the heating body 305.
`
`Besides the micro-porous ceramics, the liquid supply material of the atomizer 307
`
`may also be foamed ceramics, micro-porous glass, foamed metal, stainless steel fiber
`
`felt, terylene fiber, nylon fiber, nitrile fiber, aramid fiber or hard porous plastics. The
`
`heating body 305 may be a micro-porous ceramics holder on which electric heating
`
`materials, such as nickel-chromium alloy wire, iron-chromium alloy wire, or platinum
`
`wire, are wound. Alternatively, the heating body 305 may be a porous component
`
`made of electrically conductive ceramics or PTC (Positive Temperature Coefficient)
`
`thermosensitive ceramics, with a sintered electrode. The surface of the heating body
`
`305 is sintered into high—temperature glaze to fix the zeolite grains, which are made of
`
`natural zeolite, artificial non-organic micro-porous ceramics or aluminum oxide
`
`grains. The cigarette liquid bottle 401 and the suction nozzle 403 in the cigarette
`
`bottle assembly are made of non-toxic plastic, and inside them, the fiber 402 made of
`
`polypropylene fiber or nylon fiber to absorb cigarette liquid is adhered. In the battery
`
`assembly, there is a fine hole 501 on the indicator cap 201 for balancing the pressure
`
`difference on both sides of the silicon rubber corrugated membrane 208.
`
`The cigarette liquid for atomization contains 0.1-3.5% of nicotine, 0.05-5% of tobacco
`
`flavor, 0.1—3% of organic acid, 0.l—0.5% of stabilizer, and propanediol for the
`
`remaining.
`
`The first and second shell 211, 306 of this utility model are made of stainless steel
`
`tube or copper alloy tube with baked-enamel coating of real cigarette color.
`
`As shown in FIG. 12, this utility model may have the diameter of the battery assembly
`increased in proportion, so that it is consistent with the diameter of the atomizer
`
`assembly. Its shell may be decorated with the leaf Veins and sub-gloss brown-yellow
`
`baked—enamel coating, to create a cigar type emulation aerosol sucker.
`
`6
`
`10
`
`15
`
`20
`
`25
`
`30
`
`35
`
`40
`
`Exhibit 1004-00006
`
`

`
`For recharging of the lithium battery 203 of this utility model, the thread electrode
`
`601, as shown in Figure 6, that matches the external thread electrode 209 on the
`
`battery assembly may be used as the charging interface.
`
`Example 2
`
`10
`
`15
`
`20
`
`25
`
`30
`
`35
`
`40
`
`As shown in FIG. 2B, the differences of this example from example 1 are as follows:
`MCU 206 is added between the MOSFET electric circuit board 205 and the sensor
`
`207. On the surface of the first shell 211, there is a screen 204 for display of the
`
`battery level of the lithium battery 203 and the sucking times.
`
`As shown in FIG. 5B, the standby state of this utility model has the fully charged
`
`battery assembly shown in FIG. 2A fastened onto the atomizer assembly shown in
`
`FIG. 3, which is then inserted into the cigarette bottle assembly shown in FIG. 4.
`
`When the user slightly sucks the suction nozzle 403 with mouth, the negative pressure
`
`is formed on the silicon rubber corrugated membrane 208 through the air suction
`
`channel 503 and the first and second negative pressure cavities 210, 301. The silicon
`
`rubber corrugated membrane 208, under the action of suction pressure difference,
`
`deforms to drive the reed switch 212 and the sensor 207, thereby starting the MCU
`206 and the MOSFET electric circuit board 205. At this moment, the indicators 202
`
`are lit gradually; the lithium battery 203 electrifies a heating body 305 inside the
`
`atomizer 307 through the MOSFET electric circuit board 205 as well as the internal
`
`and external thread electrodes 302, 209, so that the heating body 305 inside the
`
`atomizer 307 produces heat. The fiber 402 inside the cigarette liquid bottle 401
`
`contains cigarette liquid, which soaks a micro-porous ceramics 801 inside the
`
`atomizer through the fiber 402. The air enters through the air intake hole 502, passes
`
`through the run-through hole on the air-liquid separator 303, and helps to form
`
`air-liquid mixture in a spray nozzle 304 of the atomizer 307. The air-liquid mixture
`
`sprays onto the heating body 305, gets vaporized, and is quickly absorbed into the
`
`airflow and condensed into aerosol, which passes through the air suction channel503
`
`and is sucked out by suction nozzle 403 to form white mist type aerosol.
`
`As shown in FIG. 7, when the action of suction actuate the sensor, the MCU 206
`
`scans the sensor 207 in the power-saving mode of pulse, and according to the signal
`
`parameters of the sensor 207, restricts the atomizing capacity with the integral
`
`function of frequency to single operation time. Also, the MCU 206 accomplishes the
`
`following control
`
`functions:
`
`the pulse width modulation and over discharging
`
`protection for the constant power output of the power supply, automatic cleaning
`
`function for thousands of times per operation, step lighting/dying down control of the
`
`indicators, display of the operation times and battery capacity, automatic recovery
`
`after sensor malfunction shutdown, etc.
`
`The apparatus and its connecting structure of this utility model may be taken as a drug
`
`7
`
`Exhibit 1004-00007
`
`

`
`delivery device of pulmonary suction with routine medicines loaded.
`
`Exhibit 1004-00008
`
`

`
`Claims
`
`1. An emulation aerosol sucker, characterized in that it includes a battery assembly, an
`
`atomizer assembly and a cigarette bottle assembly, wherein the cigarette bottle
`
`assembly includes a cigarette liquid bottle and the atomizer assembly includes an
`
`atomizer, and wherein the cigarette bottle assembly is inserted into one end of the
`
`atomizer assembly, thus forming one cigarette type or cigar type body.
`
`2. The emulation aerosol sucker of claim 1, characterized in that an external thread
`
`electrode is located in one end of the battery assembly and an internal thread electrode
`
`is located in one end of the atomizer assembly, and wherein the battery assembly and
`
`atomizer assembly are connected through the thread electrodes.
`
`3. The emulation aerosol sucker of claim 1 or 2, characterized in that the battery
`
`assembly includes a lithium battery, a MOSFTET electric circuit board, a sensor, a
`
`first thread electrode, a first negative pressure cavity, and a first shell, wherein on one
`end of the first shell is the external thread electrode, and on the other side of the first
`
`shell,
`
`the lithium battery and the MOSFET electric circuit board are connected
`
`successively, and wherein the sensor is located on the MOSFET electric circuit board.
`
`4. The emulation aerosol sucker of claim 3, characterized in that the said battery
`
`assembly further includes a silicon rubber corrugated membrane, wherein between the
`
`first thread electrode and the sensor,
`
`the silicon rubber corrugated membrane is
`
`installed, on which there is the first negative pressure cavity, and wherein the sensor is
`
`10
`
`15
`
`20
`
`25
`
`connected with the silicon rubber corrugated membrane through a reed switch fixed
`thereon.
`
`30
`
`35
`
`5. The emulation aerosol sucker of claim 3, characterized in that the battery assembly
`
`fiirther includes indicators, which are mounted on the other end of the first shell,
`
`wherein an indicator cap is provided on one side of the first shell and a fine hole is in
`
`the indicator cap, wherein MCU is provided between the MOSFET electric circuit
`
`board and the sensor, and wherein on the surface of the first shell, a screen is provided.
`
`6. The emulation aerosol sucker of claim 5, characterized in that the MCU scans the
`
`sensor in a power-saving mode of pulse, and restricts the atomizing capacity with the
`
`integral function of frequency to single operation time according to the signal
`
`parameters of the sensor, wherein the MCU also accomplishes the following controls:
`1
`
`Exhibit 1004-00009
`
`

`
`the pulse width modulation and over discharging protection for the constant power
`
`output of the electric current; automatic cleaning function for thousands of times per
`
`operation; step lighting/dying down control of the indicators; display of the operation
`
`times and battery capacity; and automatic recovery after sensor malfunction shutdown
`and wherein the indicators are two red LEDs.
`
`u
`
`7. The emulation aerosol sucker of claim 3, characterized in that the sensor is a switch
`
`sensor made of elastic alloy slice, Hall element of linear output, semiconductor
`
`10
`
`force-sensitive chip, semiconductor matrix thermoelectric bridge chip, or capacitance
`and inductance sensor.
`
`8. The emulation aerosol sucker of claim 4, characterized in that the silicon rubber
`
`corrugated membrane is made of fluorinated rubber, butyronitrile rubber, or elastic
`
`alloy film.
`
`9. The emulation aerosol sucker of claim 3, characterized in that the external thread
`
`electrode is a gold-coated stainless steel or brass part with a hole drilled in the center,
`
`and wherein the lithium battery is either a rechargeable polymer lithium battery or a
`
`rechargeable lithium ion battery.
`
`10. The emulation aerosol sucker of claim 1 or 2, characterized in that the atomizer
`
`assembly includes the internal thread electrode, an atomizer and the second shell,
`
`wherein one end of the second shell is inserted into the cigarette bottle assembly for
`
`connection, while the other end of the second shell has the internal thread electrode, in
`
`which there is the second negative pressure cavity.
`
`11. The emulation aerosol sucker of claim 3, characterized in that the atomizer
`
`assembly includes the internal thread electrode, an atomizer and the second shell,
`
`wherein one end of the second shell is inserted into the cigarette bottle assembly for
`
`connection, while the other end of the second shell has the internal thread electrode, in
`
`which there is the second negative pressure cavity.
`
`12. The emulation aerosol sucker of claim 11, characterized in that the said atomizer
`
`assembly includes an air—liquid separator, wherein the air—liquid separator and the
`
`atomizer are connected with the internal thread electrode successively, and wherein on
`
`the second shell, there is an air intake channel.
`
`15
`
`20
`
`25
`
`30
`
`35
`
`Exhibit 1004-00010
`
`

`
`13. The emulation aerosol sucker of claim 12, characterized in that the internal thread
`
`electrode is a gold-coated stainless steel or brass part with a hole drilled in the center,
`
`and wherein the air—liquid separator is made of stainless steel or plastic with a hole
`drilled.
`
`14. The emulation aerosol sucker of claim 10, characterized in that the atomizer is a
`
`capillary impregnation atomizer or a spray atomizer, inside which there is a heating
`
`body, and wherein the spray atomizer has a spray hole on it.
`
`15. The emulation aerosol sucker of claim 11, characterized in that the atomizer is a
`
`capillary impregnation atomizer or a spray atomizer, inside which there is a heating
`
`body, and wherein the spray atomizer has a spray hole on it.
`
`16. The emulation aerosol sucker of claim 15, characterized in that the spray hole is
`
`made through molding and drilling foamed ceramics, micro-porous ceramics, foamed
`
`metal, stainless steel fiber felt, or chemical fiber.
`
`17. The emulation aerosol sucker of claim 15, characterized in that the heating body is
`
`made of a micro-porous ceramics holder on which electric heating materials that are
`
`nickel-chromium alloy wire, iron-chromium alloy wire or platinum wire are wound,
`
`or the heating body is a porous component made of electrically conductive ceramics
`
`or PTC ceramics, with a sintered electrode, and wherein the surface of the heating
`
`body is sintered into high-temperature glaze to fix the zeolite grains, which are made
`
`10
`
`15
`
`20
`
`25
`
`of natural zeolite, artificial non-organic micro-porous ceramics or aluminum oxide
`grains.
`
`30
`
`35
`
`18. The emulation aerosol sucker of claim 3, characterized in that the cigarette bottle
`assembly includes a cigarette liquid bottle, fiber and a suction nozzle, wherein the
`
`fiber containing cigarette liquid is located on one end of the cigarette liquid bottle, and
`
`this end is inserted into the second shell and lies against the atomizer, wherein the
`
`suction nozzle is located on the other end of the cigarette liquid bottle, and wherein
`
`between the fiber and interior wall of the cigarette liquid bottle is an air suction
`channel.
`
`19. The emulation aerosol sucker of claim 11, characterized in that the cigarette bottle
`
`assembly includes a cigarette liquid bottle, fiber and a suction nozzle, wherein the
`
`fiber containing cigarette liquid is located on one end of the cigarette liquid bottle, and
`
`this end is inserted into the second shell and lies against the atomizer, wherein the
`3
`
`Exhibit 1004-00011
`
`

`
`suction nozzle is located on the other end of the cigarette liquid bottle, and wherein
`
`between the fiber and interior wall of the cigarette liquid bottle is an air suction
`channel.
`
`20. The emulation aerosol sucker of claim 18, characterized in that the said cigarette
`
`liquid bottle and the suction nozzle are made of non-toxic plastic, and wherein the
`
`said fiber is made of polypropylene fiber or nylon fiber.
`
`Exhibit 1004-00012
`
`

`
`Abstract
`
`The utility model relates to an electronic suction apparatus,
`
`in particular to a
`
`emulation aerosol sucker which contains only nicotine without tar. The emulation _
`
`aerosol sucker comprises a battery assembly, an atomizer assembly and a cigarette
`
`bottle assembly. An external thread electrode is located in one end of the battery
`
`assembly, and an internal
`
`thread electrode is located in one end of the atomizer
`
`assembly. The battery assembly and the atomizer assembly are connected through the
`
`thread electrodes. The cigarette bottle assembly is inserted into one end of the
`
`atomizer assembly, thus forming one cigarette type or cigar type body. The utility
`
`model contains no tar for smokers, greatly reduces carcinogenic risks, and leads users
`
`to have usual smoking feeling and excitement; the utility model does not need ignition
`
`and have fire hazard. The apparatus and the connection structure of the utility model
`
`can be taken as a drug delivery device of pulmonary suction medicines with routine
`medicines loaded.
`
`10
`
`15
`
`Exhibit 1004-00013
`
`

`
`Anlage EP3a
`
`VERIFICATION OF TRANSLATION
`
`I,
`
`CHEN Lu
`
`Peksung Intellectual Progertg Ltd.
`of
`do hereby certify that I am familiar with the English and
`lchinese languages and that to the best of my Knowledge and
`belief the following is a true translation into the English
`language of the specification of CN20lO67079Y(Application
`
`number:CN200620090805) published in Chinese.
`
`Dated this
`
`27th day of October, 2014.
`
`Signature of translator: ff? 7%
`
`CHEN Lu
`
`ExhflMt1004-00014