[ Utility model ] content
An object of the utility model is to overcome the not enough of above-mentioned technique, provide an oil core separation atomizer, can make the user have the suction of preferred when using for the first time and experience and have the taste of preferred.
The utility model provides a pair of oil core separation atomizer, including the oil cup and be located the atomizing core of the oil storage intracavity of oil cup, the air inlet of atomizing core, gas outlet set up respectively the different positions of oil cup, atomizing core includes atomizing main part and atomizing cover, atomizing cover encircles atomizing main part and having the inlet port and be used for the intercommunication the oil storage chamber with atomizing main part still includes oil removal spare and movable piece, oil removal spare is installed atomizing cover, cover when oil removal spare is located the first position the inlet port is in order to cut off the inlet port with intercommunication between the oil storage chamber, oil removal spare can move down the drive of movable piece to the second position in order to open the inlet port with the intercommunication in oil storage chamber.
Further, the movable member is a catheter; the oil removal piece is the shell-like piece that is equipped with the through-hole, and the first pot head of oil removal piece is established atomizing cover, the second end installation of oil removal piece the movable piece, keeping away from of movable piece the one end of oil removal piece is installed the induction port of oil cup, movable piece can be followed the direction removal that is close to the atomizing core, and the oil removal piece can be followed under the drive of movable piece the atomizing cover removes the second position, and makes the inlet port accessible the through-hole with the oil storage chamber intercommunication.
Further, when the oil separation piece is located at the first position, the through hole is located between the oil inlet and the air outlet.
Further, the atomizing cover is sleeved on the atomizing main body, a convex portion is formed on the periphery of the atomizing cover, and when the oil separation piece is located at the first position, the first end portion of the oil separation piece is abutted to the convex portion.
Furthermore, a concave position is formed on the inner wall of the cavity of the oil separation piece, and when the oil separation piece is located at the second position, the convex part is accommodated in the concave position and is abutted to the inner wall of the concave position.
Further, when the oil separation member is located at the second position, an end surface of the movable member, which is far away from the oil separation member, is flush or not flush with an end surface of the oil cup, which is provided with the air suction port.
An oil isolating ring is arranged between one end of the movable piece far away from the oil isolating piece and the air suction port.
Furthermore, a convex ring is formed on the inner wall of the cavity of the oil separation piece, the cavity is divided into a first cavity and a second cavity by the convex ring, the atomizing cover part is contained in the first cavity, and one end, close to the oil separation piece, of the movable piece is installed in the second cavity.
Furthermore, a compression ring is arranged between one end of the movable piece, close to the oil separation piece, and the inner wall of the second cavity.
Further, the atomizing main part is including generating heat the frame and installing the heat-generating body in the frame that generates heat, the atomizing cover surrounds the frame that generates heat, generate heat the frame have with the channel of inlet port intercommunication.
The utility model discloses an oil removal spare covers the inlet port of atomizing cover in order to block the intercommunication between inlet port and the oil storage chamber, before the user uses for the first time, the atomizing oil of oil storage intracavity can not enter into atomizing core the inside to can not produce atomizing oil and pile up, thereby can make the user have the suction of preferred when using for the first time and experience and the taste of preferred.
[ detailed description ] embodiments
The invention is further described with reference to the following figures and examples.
Referring to fig. 1 to 3, the present invention provides an oil core separation atomizer, which comprises an oil cup 10, an atomizing core, an oil separation member 30 and a movable member 40.
The inside of the oil cup 10 forms an oil storage chamber 101 for storing atomized oil, and the atomizing core is located in the oil storage chamber 101. The oil cup 10 has an air suction port 11 at one end for a user to suck, and a bottom cover 12 at the other end. The air inlet 224 and the air outlet 223 of the atomizing core are respectively arranged at different positions of the oil cup 10, in this embodiment, the air inlet 224 of the atomizing core is located in the oil cup 10 and close to the bottom cover 12, and the air outlet 223 is located in the oil cup 10 and close to the air suction port 11. A boss 15 is formed at one end of the oil cup 10, which is provided with the air suction port 11, an oil filling port 16 is formed at the end part of the boss 15, the oil filling port 16 is communicated with the oil storage cavity 101, and atomized oil can be filled into the oil storage cavity 101 through the oil filling port 16. The oil filling opening 16 is provided with a sealing member 17 for sealing the oil filling opening 16 to prevent contamination of the atomized oil. Preferably, the seal 17 is a pintle.
The atomizing core includes an atomizing body and an atomizing bell 22. The atomizing body is mounted to the bottom cover 12, and the atomizing cap 22 surrounds the atomizing body and has an oil inlet hole 221. Specifically, the atomizing cover 22 is fitted over the atomizing body. The oil inlet 221 is used to communicate the oil storage chamber 101 with the atomizing body.
In this embodiment, the atomizing main body includes a heating frame 211 and a ceramic heating element 212 mounted in the heating frame 211. The heating rack 211 is mounted to the bottom cover 12, and specifically, one end of the heating rack 211 has a mounting portion 211a, the bottom cover 12 has a mounting hole 121, and the mounting portion 211a is mounted in the mounting hole 121. The mounting portion 211a of the heat generating frame 211 has the air inlet 224. The atomizing cover 22 surrounds the heating frame 211, and specifically, the atomizing cover 22 is sleeved on the heating frame 211. The end of the atomizing hood 22 remote from the bottom cover 12 has the air outlet 223. The heat generating frame 211 has a channel 211b communicating with the oil inlet hole 221, and the channel 211b extends in the axial direction of the heat generating frame 211, so that the atomized oil entering the oil inlet hole 221 can enter the heat generating body 212 through the channel 211b, so that the heat generating body 212 heats the atomized oil. The width of the channel 211b is preferably larger than the inner diameter of the oil inlet hole 221 to facilitate the entry of the atomized oil into the heating body 212.
The electrode 13 is mounted in the mounting portion 211a, the electrode 13 is used for electrically connecting with the positive electrode of the battery pole, and the mounting portion 211a is used for connecting with the negative electrode of the battery pole. The inner cavity of the electrode 13 communicates with the inside of the mounting portion 211 a. An insulating ring 14 is provided between the electrode 13 and the inner wall of the mounting portion 211a to isolate the electrode 13 from the mounting portion 211a to prevent a short circuit therebetween. The heating element 212 is provided with a positive electrode pin and a negative electrode pin which are extended out, the positive electrode pin is in conductive connection with the electrode 13, the negative electrode pin is in conductive connection with the mounting part 211a, therefore, the electrode 13 and the positive electrode pin form a positive electrode loop of the heating element 212, the mounting part 211a and the negative electrode pin form a negative electrode loop of the heating element 212, power supply for the heating element 212 can be realized through the battery rod, and the heating element 212 can realize heating atomization of the entered atomized oil.
The oil separation member 30 is mounted to the atomizing cover 22, the oil inlet hole 221 is covered by the oil separation member 30 when the oil separation member 30 is located at the first position to block the communication between the oil inlet hole 221 and the oil storage chamber 101, and the oil separation member 30 is movable to the second position by the driving of the movable member 40 to open the communication between the oil inlet hole 221 and the oil storage chamber 101.
Specifically, in the present embodiment, the oil separator 30 is a sleeve-shaped member provided with a through hole 31, and the through hole 31 communicates with the oil storage chamber 101. The movable member 40 is a catheter. The first end of the oil separator 30 is sleeved on the atomization cover 22, and the second end of the oil separator 30 is provided with the movable member 40. When the oil separating member 30 is located at the first position, the first position is the position after the oil separating member 30 is assembled, as shown in fig. 3 and 4, the through hole 31 is located between the oil inlet 221 and the air outlet 223, and the oil separating member 30 covers the oil inlet 221 to block the communication between the oil inlet 221 and the oil storage chamber 101, so that the atomized oil in the oil storage chamber 101 cannot enter the oil inlet 221, and therefore cannot enter the heating body 212, the atomized oil cannot be accumulated, and a user can have better suction experience and better taste when the oil separating member is used for the first time. One end of the movable element 40, which is far away from the oil separating element 30, is mounted to the air inlet 11, the movable element 40 can move axially in the air inlet 11 in a direction close to the atomizing core (i.e., in the axial direction of the movable element 40), the oil separating element 30 can move along the atomizing cover 22 under the driving of the movable element 40 to a second position, which is a position where the through hole 31 is located between the oil inlet 221 and the oil storage chamber 101, as shown in fig. 5 and 6, so that the oil inlet 221 can communicate with the oil storage chamber 101 through the through hole 31, and the communication between the oil inlet 221 and the oil storage chamber 101 can be opened, and thus, the atomized oil in the oil storage chamber 101 can enter the oil inlet 221 through the through hole 31. The inner diameter of the through hole 31 is generally set to be larger than the inner diameter of the oil inlet 221 to ensure that the atomized oil can rapidly and smoothly enter the oil inlet 221.
In this embodiment, two oil inlets 221 are provided, the two oil inlets 221 are disposed oppositely, and the number and the positions of the through hole 31 and the groove 211b correspond to those of the oil inlets 221. It is understood that the oil inlet hole 221 may be plural, and the plural oil inlet holes 221 are provided along the circumferential direction of the atomizing housing 22. The number of the oil inlet holes 221, the through holes 31, and the grooves 211b may be set according to actual circumstances.
When the oil separator 30 moves to the second position under the driving of the movable member 40, the first end of the oil separator 30 abuts against the bottom cover 12, thereby positioning the second position of the oil separator 30.
Before the user uses the oil separator 30 for the first time, the oil separator 30 is located at the first position, and at this time, the oil inlet hole 221 and the oil storage chamber 101 are isolated from each other by the oil separator 30. When a user uses the atomizing hood for the first time, the end of the movable member 40 far away from the oil separating member 30 can be pressed downwards by hands or other auxiliary tools, the oil separating member 30 can be driven by the movable member 40 to move to the second position along the atomizing hood 22, at this time, the through hole 31 of the oil separating member 30 corresponds to the oil inlet hole 221, as shown in fig. 5 and 6, so that the atomized oil in the oil storage chamber 101 can enter the oil inlet hole 221 through the through hole 31 and then enter the heating element 212 through the channel 211b of the heating frame 211, when the user sucks at the air suction port 11, the heating element 212 can heat and atomize the atomized oil, and the heated and atomized gas is mixed with the air entering from the inner cavity 131 of the electrode 13 and the air inlet 224 of the atomizing core, and then enters the oil separating member 30 through the air outlet 223 of the atomizing core and then enters the movable member 40, so as to be finally sucked by the user.
A protrusion 222 is formed on the outer periphery of one end of the atomizing cover 22 close to the bottom cover 12, and when the oil barrier 30 is located at the first position, the first end of the oil barrier 30 abuts against the protrusion 222, as shown in fig. 3 and 4, thereby positioning the first position of the oil barrier 30.
The cavity inner wall of the oil separating member 30 is formed with a concave position 32, as shown in fig. 4, the concave position 32 corresponds to the oil inlet 221, and when the oil separating member 30 is located at the second position, the convex portion 222 is accommodated in the concave position 32 and abuts against the inner wall of the concave position 32, as shown in fig. 5 and 6, a sealing function is performed to prevent the atomized oil from leaking from between the atomizing cover 22 and the first end of the oil separating member 30, and a function of positioning the second position of the oil separating member 30 is also performed.
Further, the inner wall of the cavity of the oil separator 30 is formed with the sealing protrusions 36 above and below the through hole 31, as shown in fig. 4, when the oil separator 30 is located at the first position, the two sealing protrusions 36 abut against the atomizing cover 22 to perform a sealing function, so as to prevent the atomized oil in the oil storage cavity 101 from entering between the inner wall of the cavity of the oil separator 30 and the atomizing cover 22 from the through hole 31 and further entering the oil inlet 221. When the oil separating member 30 is located at the second position, as shown in fig. 6, the two sealing protrusions 36 are located above and below the oil inlet 221 respectively, so as to ensure that the atomized oil smoothly enters the oil inlet 221 from the through hole 31 and does not enter between the inner wall of the cavity of the oil separating member 30 and the atomizing cover 22.
In this embodiment, a protruding ring 33 is formed on the inner wall of the oil separator 30, the protruding ring 33 divides the cavity into a first cavity 34 and a second cavity 35, as shown in fig. 4, the atomizing cover 22 is partially accommodated in the first cavity 34, and one end of the movable member 40 close to the oil separator 30 is mounted in the second cavity 35.
Preferably, a compression ring 60 is provided between one end of the movable member 40 close to the oil barrier 30 and the inner wall of the second chamber 35. The pressing ring 60 serves as a seal to prevent the atomized oil in the oil reservoir 101 from entering the movable member 40.
The end surface of the movable member 40 remote from the oil barrier 30 is not flush with the end surface of the oil cup 10 having the suction port 11. In this embodiment, an end surface of the movable element 40 away from the oil separator 30 protrudes from an end surface of the oil cup 10 having the air inlet 11, so that the end of the movable element 40 away from the oil separator 30 can be pressed downward. When the movable member 40 is pressed downward so that the oil barrier 30 is located at the second position, an end surface of the movable member 40 remote from the oil barrier 30 is flush with an end surface of the oil cup 10 having the suction port 11, as shown in fig. 5.
It will be appreciated that in an alternative, the end surface of the movable element 40 remote from the oil barrier 30 may also be located below the end surface of the oil cup 10 having the suction port 11.
It will be appreciated that in a further alternative, the end face of the movable member 40 remote from the oil barrier 30 is flush with the end face of the oil cup 10 having the suction opening 11. When the oil separator 30 is positioned at the second position by pressing the movable element 40 downward, the end surface of the movable element 40 remote from the oil separator 30 is positioned below the end surface of the oil cup 10 having the suction port 11.
The end surface of the movable element 40 far from the oil separator 30 is not flush or flush with the end surface of the oil cup 10 having the air inlet 11, and can be selected according to actual conditions.
Preferably, an oil-separating ring 50 is provided between the end of the movable element 40 remote from the oil-separating element 30 and the suction port 11. The oil ring 50 seals the oil mist in the oil storage chamber 101 from leaking out through the suction port 11.
The above examples only represent preferred embodiments of the present invention, which are described in more detail and detail, but are not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the concept of the present invention, several variations and modifications can be made, such as combinations of different features in the various embodiments, which are within the scope of the present invention.