Disclosure of Invention
The invention aims to overcome the defects in the prior art and provides an atomizer and an electronic atomization device for solving the technical problems.
The aim of the invention is realized by the following technical scheme:
the atomizer comprises an oil bin assembly and a heating assembly, wherein the oil bin assembly comprises an oil cup part and a movable plug, the oil cup part is provided with an oil storage cavity, a flow guide channel and a first oil inlet hole, the oil storage cavity is communicated with the flow guide channel through the first oil inlet hole, the movable plug is located in the flow guide channel and is elastically abutted to the oil cup part, the movable plug is movably connected to the oil cup part, the movable plug is provided with an air passing hole communicated with the flow guide channel, the movable plug is staggered with the first oil inlet hole, the heating assembly is detachably connected with the oil cup part, and the heating assembly is located in the flow guide channel and is abutted to the movable plug and is correspondingly arranged with the first oil inlet hole so as to heat and atomize tobacco tar.
In one embodiment, the movable plug is slidably coupled to the oil cup.
In one embodiment, the oil cup is further provided with an open slot, the oil storage cavity and the flow guide channel are both communicated with the open slot, and the heating component is positioned in the open slot and is detachably connected with the oil cup piece;
The oil bin assembly further comprises a sealing plug, wherein the sealing plug is located in the oil storage cavity and elastically abuts against the oil cup piece to seal the oil storage cavity.
In one embodiment, the oil cup comprises an oil cup and a central tube, the oil storage cavity is formed in the oil cup, the flow guide channel and the first oil inlet are formed in the central tube, the central tube is located in the oil storage cavity and connected with the oil cup, the sealing plug is sleeved on the central tube, the movable plug is elastically abutted to the central tube, the movable plug is slidably connected to the central tube, and the oil cup is detachably connected with the heating component.
In one embodiment, the oil cup is further provided with an air outlet hole, the air outlet hole is communicated with the oil storage cavity, the central tube is arranged around the air outlet hole, and the flow guide channel is communicated with the air outlet hole.
In one embodiment, the heat generating component comprises:
The atomization connecting seat is provided with an air inlet hole, a second oil inlet hole and an atomization cavity, the air inlet hole and the second oil inlet hole are both communicated with the atomization cavity, the atomization cavity is communicated with the diversion channel, and the atomization connecting seat is positioned in the diversion channel and detachably connected with the oil cup;
The atomization piece is located in the atomization cavity and connected with the atomization connecting seat, the peripheral wall of the atomization piece corresponds to the second oil inlet hole, the atomization channel is formed in the atomization piece, and the atomization cavity is respectively communicated with the air inlet hole and the atomization channel.
In one embodiment, the atomization connecting seat comprises a connecting seat and an atomization pipe which are connected, the air inlet is formed in the connecting seat and used for being detachably connected with the oil cup, the second oil inlet and the atomization cavity are formed in the atomization pipe and used for being detachably connected in the flow guide channel, and the atomization pipe is abutted to the movable plug and communicated with the air passing hole.
In one embodiment, the connecting seat is further provided with a mounting hole communicated with the air inlet hole, and a part of the atomization tube is positioned in the mounting hole and connected with the connecting seat.
In one embodiment, the atomizing tube is sleeved at one end of the movable plug.
An electronic atomizer comprising an atomizer as in any one of the embodiments above.
Compared with the prior art, the invention has at least the following advantages:
1. According to the atomizer, the heating component is detachably connected with the oil cup, namely the oil bin component is detachably connected with the heating component, so that the heating component can be detached from the oil bin component for multiple use; for the oil bin assembly, because the movable plug is positioned in the diversion channel and elastically abuts against the oil cup, and the movable plug can be movably connected with the oil cup, before the oil bin assembly is used, the movable plug is positioned in the diversion channel and is correspondingly arranged with the first oil inlet, so that the movable plug can block the first oil inlet, reliable transportation of tobacco tar is realized, the problem that the traditional oil bin assembly is easy to leak oil in the transportation process is solved;
2. when the smoke-collecting device is used, the oil bin assembly and the heating assembly are assembled together, namely the heating assembly is assembled and connected with the oil cup, the heating assembly is correspondingly arranged with the first oil inlet hole, the movable plug is staggered with the first oil inlet hole, smoke oil in the oil storage cavity enters the diversion channel through the first oil inlet hole to be abutted with the heating assembly, and the heating assembly heats and atomizes the smoke oil to form atomized gas;
3. Because the oil bin assembly is detachably connected with the heating assembly, when the tobacco tar in the oil storage cavity is used, namely, when the tobacco tar in the oil storage cavity is used, the oil bin assembly is replaced, that is, the oil bin assembly is detached, the electronic atomization device can be reused, the electronic atomization device is convenient and fast, and meanwhile, the problem that the traditional oil bin assembly and the heating assembly are discarded together to enable the electronic atomization device to be poor in environmental protection is solved.
Detailed Description
In order that the invention may be readily understood, a more complete description of the invention will be rendered by reference to the appended drawings. The drawings illustrate preferred embodiments of the invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.
It will be understood that when an element is referred to as being "fixed to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like are used herein for illustrative purposes only and are not meant to be the only embodiment.
Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.
The application provides an atomizer which comprises an oil bin assembly and a heating assembly, wherein the oil bin assembly comprises an oil cup part and a movable plug, the oil cup part is provided with an oil storage cavity, a flow guide channel and a first oil inlet hole, the oil storage cavity is communicated with the flow guide channel through the first oil inlet hole, the movable plug is positioned in the flow guide channel and is elastically abutted to the oil cup part, the movable plug can be movably connected to the oil cup part, the movable plug is provided with an air passing hole communicated with the flow guide channel, the movable plug is staggered with the first oil inlet hole, the heating assembly is detachably connected with the oil cup part, and the heating assembly is positioned in the flow guide channel and is abutted to the movable plug and is correspondingly arranged with the first oil inlet hole so as to heat and atomize tobacco tar.
According to the atomizer, the heating component and the oil cup piece are detachably connected, namely the oil bin piece and the heating component are detachably connected, so that the heating component can be detached from the oil bin piece so as to be used for multiple times, before the atomizer is used, the oil bin piece and the heating component can be packaged and transported respectively, the movable plug is arranged in the diversion channel and is elastically abutted to the oil cup piece, and can be movably connected to the oil cup piece, before the atomizer is used, the movable plug is arranged in the diversion channel and corresponds to the first oil inlet hole, the first oil inlet hole is plugged by the movable plug, reliable transportation of tobacco tar is realized, the problem that the traditional oil bin piece is easy to leak oil in the transportation process is solved, the oil bin piece is free of heating devices, the whole structure is simple and easy to manufacture, namely the process of the whole structure is simple, the cost of the oil bin piece is low, when the atomizer is used, the oil bin piece and the heating component are assembled together, namely the heating component is assembled and connected to the oil cup piece, the heating component and the first oil inlet hole are correspondingly arranged, and the movable plug and the first oil inlet hole are arranged in the diversion channel and correspond to the first oil inlet hole, and the smoke bin piece is convenient to detach and the atomizer, and the problem that the traditional oil bin piece is easy to detach and the oil bin piece to be replaced when the smoke is used.
Referring to fig. 1, a schematic diagram of an atomizer 10 according to an embodiment is shown.
The atomizer 10 of one embodiment includes a sump assembly 100 and a heat generating assembly 300, the sump assembly 100 being removably coupled to the heat generating assembly 300 such that the sump assembly 100 may be periodically replaced. In this embodiment, the cartridge assembly 100 is used to store tobacco tar and the heater assembly 300 is used to heat the atomized tobacco tar. The oil bin assembly 100 comprises an oil cup 110 and a movable plug 130, wherein the oil cup 110 is provided with an oil storage cavity 112, a diversion channel 114 and a first oil inlet hole 116, and the oil storage cavity 112 is communicated with the diversion channel 114 through the first oil inlet hole 116. The oil cup 110 is detachably connected to the heat generating component 300, so that the heat generating component 300 is detachably connected to the oil sump component 100.
The movable plug 130 is located in the flow guiding channel 114 and elastically abuts against the oil cup 110, and the movable plug 130 is movably connected to the oil cup 110, so that the connection position between the movable plug 130 and the oil cup 110 is adjustable. The movable plug 130 is provided with an air passing hole 132 communicated with the diversion channel 114. Referring also to fig. 2, the movable plug 130 is configured to be disposed corresponding to the first oil inlet hole 116 before use, so as to block the first oil inlet hole 116. The heating assembly 300 is detachably connected with the oil cup 110, and in use, the heating assembly 300 is assembled and connected with the oil cup 110. The heating component 300 is partially located in the diversion channel and abuts against the movable plug 130, and the heating component 300 is disposed corresponding to the first oil inlet, so that the tobacco tar enters through the first oil inlet and contacts with the heating component 300, so as to heat and atomize the tobacco tar.
The movable plug 130 is staggered with the first oil inlet, that is, the movable plug 130 is used for abutting against the heating assembly 300 when in use, and moves to a position staggered with the first oil inlet relative to the oil cup 110. When the oil bin assembly 100 is connected with the heating assembly 300, the movable plug 130 abuts against the heating assembly 300 and moves to a position offset from the first oil inlet hole 116 relative to the oil cup 110, so that the tobacco tar can pass through the first oil inlet hole 116. In this embodiment, the movable plug 130 is located in the flow guiding channel 114 and elastically abuts against the oil cup 110, and the movable plug 130 can be movably connected to the oil cup 110, so that the relative connection position between the movable plug 130 and the oil cup 110 can be adjusted. Referring to fig. 2, before use, the piston member is disposed corresponding to the first oil inlet 116 to block the first oil inlet 116, so that the tobacco tar in the oil storage cavity 112 cannot enter the diversion channel 114 through the first oil inlet 116, and at this time, the tobacco tar in the oil storage cavity 112 cannot enter the second oil inlet 314 and the atomization cavity 316 through the first oil inlet 116, and the oil path is in a non-conductive state.
According to the atomizer 10, the heating component 300 is detachably connected with the oil cup 110, namely the oil bin component 100 and the heating component 300 are detachably connected, so that the heating component 300 can be detached from the oil bin component 100 for multiple use, before the atomizer is used, the oil bin component 100 and the heating component 300 can be packaged and transported respectively, the movable plug 130 is positioned in the diversion channel and elastically abutted with the oil cup 110, and the movable plug 130 can be movably connected with the oil cup 110, before the atomizer is used, the movable plug 130 is positioned in the diversion channel and is correspondingly arranged with the first oil inlet, so that the movable plug 130 seals the first oil inlet, reliable transportation of tobacco tar is realized, the problem that the traditional oil bin component 100 is easy to leak oil in the transportation process is solved, the oil bin component 100 has no heating device, has fewer parts, has simple integral structure and is easy to manufacture, namely the process of the integral structure is simple, the cost of the oil bin component 100 is lower, when the atomizer is used, the oil bin component 100 and the heating component 300 are assembled together, the movable plug 130 is movably connected with the oil cup 110, namely the movable plug 130 is arranged in the diversion channel and is correspondingly arranged with the first oil inlet, namely the tobacco bin component 300 is convenient to be replaced, namely the tobacco bin component 300 is arranged in the first oil inlet, and is convenient to be atomized, and is completely, and the tobacco bin component 300 is completely replaced, and is completely, and the tobacco bin component is completely is arranged with the first oil inlet, and is completely, and is convenient to be arranged with the first oil inlet, and is filled into the tobacco bin component 300, and is correspondingly arranged in the first oil inlet, and is filled into the tobacco bin component 100, and is convenient to be atomized and is the oil bin component and is filled, and simultaneously, the problem that the use environment protection of the electronic atomization device is poor due to the fact that the conventional oil sump assembly 100 and the heating assembly 300 are discarded together is avoided.
As shown in fig. 1, in one embodiment, the heat generating assembly 300 includes an atomizing attachment base 310 and an atomizer 320. The atomization connecting seat 310 is provided with an air inlet 312, a second oil inlet 314 and an atomization cavity 316, the air inlet 312 and the second oil inlet 314 are both communicated with the atomization cavity 316, and the atomization cavity 316 is communicated with the diversion channel 114. The atomization connecting base 310 is detachably connected to the flow guiding channel 114. When the atomization connecting seat is assembled to the oil cup 110, the atomization connecting seat abuts against and pushes the movable plug 130 to move relative to the oil cup 110 to a position where the first oil inlet 116 is communicated with the second oil inlet 314. The atomization connecting seat is abutted to the movable plug 130, and the first oil inlet is communicated with the second oil inlet. That is, when in use, the atomization connecting seat 310 is completely inserted into the flow guiding channel 114, that is, the atomization connecting seat 310 is assembled and connected in the flow guiding channel 114, the movable plug 130 moves to a position where the first oil inlet 116 is communicated with the second oil inlet 314 relative to the oil cup 110, and at this time, the first oil inlet 116 is communicated with the second oil inlet 314.
In one embodiment, as shown in fig. 1, the atomizer 320 is disposed in the atomization cavity 316 and connected to the atomization connecting base 310, and the outer peripheral wall of the atomizer 320 is disposed corresponding to the second oil inlet 314, so that the tobacco tar in the oil storage cavity 112 enters the atomization cavity 316 through the first oil inlet 116 and the second oil inlet 314 to contact with the atomizer 320, and the atomizer 320 is used for heating the tobacco tar to form atomized gas. The atomizing member 320 is provided with an atomizing channel 322, and the atomizing chamber 316 is respectively communicated with the air inlet 312 and the atomizing channel 322, so that the atomizing gas flows out through the atomizing channel 322, the atomizing chamber 316, the air passing hole 132 and the flow guiding channel 114 in sequence. In this embodiment, the atomization connecting base 310 abuts against the movable plug 130, so that the movable plug 130 is supported and limited by the atomization connecting base 310. The first oil inlet 116 is in opposite communication with the second oil inlet 314, so that the tobacco tar enters the atomization cavity 316 through the first oil inlet 116 and the second oil inlet 314.
Referring also to fig. 2, in one embodiment, the movable plug 130 is slidably coupled to the oil cup 110, such that the movable plug 130 is movably coupled to the oil cup 110. In this embodiment, the atomization connecting seat 310 is connected with the oil cup 110 in a plugging manner, the movable plug 130 is slidably connected with the oil cup 110, so that the atomization connecting seat 310 pushes the movable plug 130 to slide relative to the oil cup 110 while being plugged and assembled in the oil cup 110, the connection position of the movable plug 130 and the oil cup 110 is adjusted, the assembly time of the heating component 300 and the oil bin component 100 is greatly shortened, and the use convenience of the atomization component 320 is improved. It should be noted that, in other embodiments, the movable plug 130 is not limited to be connected to the oil cup 110 by a sliding connection, and the connection position of the movable plug 130 and the oil cup 110 may be adjusted. The movable plug 130 can also be connected to the oil cup 110 in a rotary connection manner, that is, the piston member is rotatably connected to the oil cup 110, so as to realize adjustment of the connection position of the movable plug 130 and the oil cup 110. Specifically, the atomization connecting seat 310 is in threaded connection with the oil cup 110, and a part of the atomization connecting seat 310 abuts against the movable plug 130 and drives the movable plug 130 to rotate relative to the oil cup 110.
As shown in fig. 1 and fig. 2, in one embodiment, the oil cup 110 is further provided with an opening groove 113, the oil storage cavity 112 and the air guide channel 114 are both communicated with the opening groove 113, when the oil bin assembly 100 is assembled, the sealing plug 120 can be connected to the inner wall of the oil storage cavity 112 in a sealing manner through the opening groove 113, the movable plug 130 can be installed in the air guide channel 114 through the opening groove 113, and the processing of the oil storage cavity 112 and the air guide channel and the filling of tobacco tar in the oil storage cavity 112 are convenient. The heating component 300 is located in the open slot and detachably connected to the oil cup 110, so that the heating component 300 is quickly connected and assembled with the oil cup 110. The oil bin assembly 100 further comprises a sealing plug 120, wherein the sealing plug 120 is positioned in the oil storage cavity and elastically abuts against the oil cup 110, so as to seal the oil storage cavity, so that tobacco tar in the oil storage cavity cannot leak out through the open slot, and can only enter the atomization cavity 316 to contact with the atomization piece 320 through the first oil inlet 116 and the second oil inlet 314. In this embodiment, the atomization connecting seat 310 is located in the opening groove 113 and detachably connected with the oil cup 110, and the atomization connecting seat is further abutted to the sealing plug, so that the atomization connecting seat 310 is detachably connected with the oil cup 110 through the opening groove 113, and further the connection between the atomization connecting seat 310 and the oil cup 110 is more convenient.
As shown in fig. 1 and 2, in one embodiment, the oil cup 110 includes an oil cup 110a and a central tube 110b, wherein the oil storage cavity 112 is disposed in the oil cup 110a, and the flow guiding channel 114 and the first oil inlet hole 116 are both disposed in the central tube 110b. The center tube 110b is located in the oil reservoir 112 and is connected to the oil cup 110 a. The oil cup 110a is detachably connected to the heat generating component 300, so that the heat generating component 300 is detachably connected to the oil cup 110. The sealing plug 120 is located in the oil storage cavity 112 and elastically abuts against the oil cup 110 to seal the oil storage cavity 112. The sealing plug 120 is sleeved on the central tube 110b, and the movable plug 130 elastically abuts against the central tube 110b, so that the sealing plug 120 seals the oil storage cavity 112 better. The movable plug 130 is slidably connected to the central tube 110b, so that the movable plug 130 is slidably connected to the atomizing attachment 310.
When the oil bin assembly 100 is connected with the atomization connecting seat 310 in use, the movable plug 130 is abutted with the atomization connecting seat 310 and moves to a position staggered from the first oil inlet hole 116 relative to the oil cup 110a, so that the tobacco tar in the oil storage cavity 112 can enter the atomization cavity 316 through the first oil inlet hole 116 and the second oil inlet hole 314 to be contacted with the atomization piece 320, and the atomization piece 320 atomizes the tobacco tar to form atomized gas.
It is understood that the oil cup 110a and the center tube 110b may be formed and integrally connected to each other, or may be formed integrally. As shown in fig. 1 and 2, in the present embodiment, the oil cup 110a and the center tube 110b are each formed and integrally connected. In one embodiment, an insertion boss 112a is protruding on the inner wall of the oil storage cavity 112, the insertion boss 112a is provided with an insertion groove 1122, the insertion groove 1122 is communicated with the air outlet hole 111, and the central tube 110b is located in the insertion groove 1122 and is inserted into the insertion boss 112a, so that the central tube 110b is integrally connected with the oil cup 110 a. Specifically, the central tube 110b is in interference fit with the plugging boss 112a, so that the central tube 110b is tightly connected with the plugging boss 112a, and the sealing performance of the connection between the central tube 110b and the plugging boss 112a is improved.
As shown in fig. 1 and 2, further, the movable plug 130 is a silica gel plug, so that the movable plug 130 is located in the diversion channel 114 and is elastically connected with the oil cup 110. In this embodiment, the movable plug 130 is located in the flow guiding channel 114 and elastically connected to the central tube 110b, so that the movable plug 130 is tightly connected to the inner wall of the central tube 110b, and thus, before use, the position of the movable plug 130 corresponding to the first oil inlet 116 in the flow guiding channel 114 can reliably seal the first oil inlet 116.
Further, a first sealing flange is convexly provided on an outer wall of the sealing plug 120, and the first sealing flange elastically abuts against an inner wall of the oil storage cavity 112, so that the sealing plug 120 is tightly connected to the inner wall of the oil storage cavity 112. Further, the sealing plug 120 is disposed around the outer peripheral wall of the central tube 110b, and a second sealing flange is protruding on the inner wall of the sealing plug 120 sleeved with the central tube 110b, and the second sealing flange elastically abuts against the outer peripheral wall of the central tube 110b, so that the sealing plug 120 is tightly sleeved on the outer peripheral wall of the central tube 110 b. In this embodiment, the sealing plug 120 is a silica gel plug, so that the sealing plug 120 has better elasticity, and further the sealing plug 120 can be tightly connected with the inner wall of the oil storage cavity 112 and the central tube 110b respectively. It will be appreciated that in other embodiments, the sealing plug 120 is not limited to a silicone plug, but may be a rubber plug.
The atomization connecting base 310 is also abutted against the sealing plug 120, so that the atomization connecting base 310 reliably supports and positions the sealing plug 120, and the sealing plug 120 is prevented from moving away relative to the oil cup 110 to cause the smoke and oil in the oil storage cavity 112 to leak. In this embodiment, the open slot 113 is formed in the oil cup 110a, and the atomization connecting base 310 is located in the open slot 113 and is connected to the oil cup 110a in a plug-in manner. One end of the central tube 110b is communicated with the open groove 113, and the other end is communicated with the air outlet hole 111, so that the movable plug 130 can be assembled in the flow guide channel 114 through the open groove 113, and meanwhile, the flow guide channel 114 is communicated with the air outlet hole 111. It will be appreciated that in other embodiments, the open slot 113 may be omitted, and the movable plug 130 may also be fitted into the flow guiding channel 114 through the air outlet 111. The oil cup 110a has an oil filling hole formed in its surface and communicating with the oil storage chamber 112, and tobacco tar is filled into the oil storage chamber 112 through the oil filling hole.
Referring to fig. 1 and 3, in an embodiment, in use, the oil bin assembly 100 is plugged with the atomization connecting seat 310, and the movable plug 130 is abutted with the atomization connecting seat 310, so that the movable plug 130 slides relative to the oil cup 110a to a position staggered with the first oil inlet hole 116, that is, the movable plug 130 slides relative to the oil cup 110a to a position staggered with the first oil inlet hole 116 under the thrust of the atomization connecting seat 310, so that the tobacco tar in the oil storage cavity 112 can enter the atomization cavity 316 through the first oil inlet hole 116 and the second oil inlet hole 314 to contact with the atomization element 320, and at the moment, both the oil path and the gas path are in a conducting state, so that the atomization element 320 atomizes the tobacco tar to form atomized gas.
As shown in fig. 1 and fig. 2, in one embodiment, the oil cup 110a is further provided with an air outlet hole 111, the air outlet hole 111 is communicated with the oil storage cavity 112, the central tube 110b is disposed around the air outlet hole 111, and the flow guiding channel 114 is communicated with the air outlet hole 111, so that atomized gas can flow out through the flow guiding channel 114 and the air outlet hole 111, and meanwhile, the air outlet hole 111 and the oil storage cavity 112 are separated from each other by the central tube 110b, so as to prevent smoke and oil from leaking out through the oil storage cavity 112 and the air outlet hole 111.
As shown in fig. 1 and 4, in one embodiment, the atomizing attachment 310 includes an attachment 310a and an atomizing tube 310b that are connected. The air inlet 312 is disposed on the connecting seat 310a, and the connecting seat 310a is detachably connected to the oil cup 110. The second oil inlet 314 and the atomization cavity 316 are both disposed on the atomization tube 310b, the atomization tube 310b is detachably connected to the flow guiding channel 114, and the atomization tube is abutted to the movable plug 130 and is communicated with the air passing hole. The atomization pipe abuts against and pushes the movable plug 130 to move relative to the oil cup 110 to a position where the first oil inlet 116 is communicated with the second oil inlet 314, so that the tobacco tar in the oil storage cavity 112 can enter the atomization cavity 316 through the first oil inlet 116 and the second oil inlet 314 and be heated and atomized by the atomizer 320. In this embodiment, the connection seat 310a is used for being connected to the oil cup 110 in a plugging manner. The atomizer 320 is located in the atomization chamber 316 and connected to the atomization tube 310b, so that the tobacco tar enters the atomization chamber 316 for heating and atomization. The atomizing tube 310b has a tubular structure, and the atomizing tube 310b is inserted into the diversion channel 114 and abuts against the movable plug 130, so that the movable plug 130 abuts against the atomizing connecting seat 310.
As shown in fig. 1 and 4, in one embodiment, the connection seat 310a is further provided with a mounting hole 313 that communicates with the air inlet 312, and a portion of the atomizing tube 310b is located in the mounting hole 313 and is connected to the connection seat 310a, so that the connection seat 310a is fixedly connected to the atomizing tube 310 b. It will be appreciated that in other embodiments, the mounting holes 313 may be omitted and the connection base 310a and the atomizing tube 310b may be fixedly connected by welding or gluing. Or the connection base 310a and the atomizing tube 310b are integrally formed, so that the connection base 310a and the atomizing tube 310b are fastened and connected.
In one embodiment, the atomizing tube is sleeved at one end of the movable plug 130, so that the atomizing tube is reliably abutted against the movable plug 130. As shown in fig. 1,2 and 4, in one embodiment, the end of the movable plug 130 is formed with a wedge-shaped end 133, and the atomization connecting seat 310 is detachably sleeved on the wedge-shaped end 133, so that the atomization tube is sleeved on one end of the movable plug 130, and the tightness of the connection between the movable plug 130 and the atomization connecting seat 310 is ensured, so that the atomization tube is reliably communicated with the air passing hole. In this embodiment, the atomization connecting base 310 is pluggable and sleeved at the wedge-shaped end 133, and the atomization connecting base 310 is pluggable and connected to the oil cup 110, so that the atomization connecting base 310 is fast and reliably pluggable and connected to the oil cup 110, and meanwhile, the movable plug 130 is reliably abutted to the atomization connecting base 310. Specifically, the atomizing tube 310b is inserted and sleeved at the wedge-shaped end 133, so that the atomizing tube 310b is quickly inserted and sleeved at the movable plug 130 through the flow guiding channel 114, and the atomizing tube 310b is reliably abutted to the movable plug 130. It can be understood that an insertion gap exists between the end of the movable plug 130, where the wedge-shaped end 133 is formed, and the inner wall of the flow guiding channel 114 of the oil cup 110, and the atomizing tube 310b is inserted into the insertion gap through the flow guiding channel 114 and abuts against the movable plug 130, so that the atomizing tube 310b can be quickly and accurately inserted and connected with the wedge-shaped end 133, and further, the atomized gas in the atomizing cavity 316 is reliably aligned and communicated with the gas passing hole 132 through the atomizing cavity 316.
As shown in fig. 1 and 4, further, the outer wall of the atomizing tube 310b is provided with a first annular groove 315, the atomizing connecting seat 310 further includes a first sealing ring 317, the first sealing ring 317 is convexly disposed in the first annular groove 315, and the first sealing ring 317 elastically abuts against the inner wall of the flow guiding channel 114, so that the atomizing tube 310b is inserted into the flow guiding channel 114 to be tightly connected with the oil cup 110. In this embodiment, the second oil inlet 314 is located between the first annular groove 315 and the insertion gap, so that the tobacco tar reliably enters the atomization cavity 316 through the first oil inlet 116 and the second oil inlet 314.
As shown in fig. 1 and fig. 4, in order to make the connection base 310a tightly inserted into the oil cup 110, further, the atomization connection base 310 further includes a second sealing ring 318, a second annular groove 319 is formed on an outer wall of the connection base 310a, the second sealing ring 318 is convexly disposed on the second annular groove 319, and the second sealing ring 318 elastically abuts against an inner wall of the opening groove 113, so that the connection base 310a is tightly inserted into the oil cup 110.
In order to reliably fix the atomizing member 320 and the oil cup member 110, further, at least two supporting protruding columns are protruding on the inner wall of the flow guiding channel 114 of the oil cup member 110, and the at least two supporting protruding columns are both supported and abutted to the atomizing member 320 so as to support and position the atomizing member 320, so that the atomizing member 320 is prevented from moving relative to the oil cup member 110 to influence the heating and atomization of the atomizing member 320 on the tobacco tar. Of course, in other embodiments, the inner wall of the flow guiding channel 114 of the oil cup 110 is not limited to the manner of protruding the supporting protruding columns to fix the position of the atomizing member 320, and the inner wall of the flow guiding channel 114 of the oil cup 110 may be provided with a positioning groove to fix the position of the atomizing member 320.
As shown in fig. 1 and 4, further, the atomization member 320 includes an oil guiding member 320a and a conductive heating member 320b, the oil guiding member 320a wraps the conductive heating member 320b, the oil guiding member 320a is located in the atomization cavity 316 and is connected with the atomization tube 310b, the conductive heating member 320b is used for heating and atomizing the oil guiding member 320a when being electrified, the oil guiding member 320a is correspondingly arranged with the second oil passing hole, so that the tobacco tar passing through the second oil passing hole contacts the oil guiding member 320a, and is transmitted to the conductive heating member 320b through the oil guiding member 320a for heating and atomizing. In this embodiment, the oil guide 320a is an oil guide cotton, so that the oil guide 320a has a better oil guiding effect. Further, the conductive heating element 320b is a spiral conductive heating coil, so that the conductive heating element 320b uniformly heats the tobacco tar at each position in the oil guiding element 320a, and the heating effect of the conductive heating element 320b is improved. In order to mix the peripheral air flow with the atomized tobacco tar vapor well to form atomized gas, further, an atomization channel 322 is formed in the center of the oil guiding member 320a, and a conductive heating member 320b is disposed around the atomization channel 322, so that the atomized tobacco tar vapor generated by heating the atomized tobacco tar by the conductive heating member 320b is mixed with the air flow rapidly and uniformly to form atomized gas well. It should be noted that, in other embodiments, the oil guiding member 320a is not limited to the oil guiding cotton member, but may be a ceramic member.
It can be understood that when the atomizer 320 heats and atomizes the tobacco tar, condensate is present at each position of the atomizer 320 due to uneven heating, so that condensate drops at the bottom of the atomizer 320, and thus the condensate easily flows out through the air inlet 312 and damages electronic components such as the battery pole. In order to avoid the problem that condensate easily flows out through the air inlet 312 and damages electronic components such as a battery rod, as shown in fig. 1 and 4, in one embodiment, the connection base 310a is further provided with a buffer slot 321, and the buffer slot 321 is respectively communicated with the air inlet 312 and the atomizing chamber 316. The communication position between the air inlet 312 and the buffer tank is at a preset height with the bottom of the buffer tank 321. In this embodiment, the buffer slot 321 is located below the atomization cavity 316, so that condensate generated by the atomization component 320 in the process of atomizing tobacco tar is buffered in the buffer slot 321, and the problem that the condensate flows out easily through the air inlet 312 and damages electronic components such as a battery rod due to the preset height between the communication position of the air inlet 312 and the buffer slot and the bottom of the buffer slot 321 is avoided. Specifically, the connection base 310a includes a connection base main body 3102, an insulating sealing block 3104 and a conductive pole 3106, the buffer groove 321 and the mounting hole 313 are both formed in the connection base main body 3102, the atomization tube 310b is located in the mounting hole 313 and is connected with the connection base main body 3102, and the connection base main body 3102 is further provided with a sealing fixing hole 3101 communicated with the buffer groove 321. The insulating sealing block 3104 is sleeved on the conductive electrode column 3106 and connected with the conductive electrode column 3106, and the insulating sealing block 3104 is penetrated in the sealing fixing hole 3101 and connected with the connection seat main body 3102 in a sealing manner. The air inlet hole 312 is formed at the end part of the conducting electrode column 3106 located in the buffer groove 321, so that a preset height exists between the position of the air inlet hole 312 communicated with the buffer groove 321 and the bottom of the buffer groove 321, and the conducting electrode column 3106 is in sealing connection and insulation with the connecting seat main body 3102 through the insulating sealing block 3104. In this embodiment, the conductive electrode post 3106 is electrically connected with the positive electrode of the conductive heating element 320b, and the connection base main body 3102 is electrically connected with the negative electrode of the conductive heating element 320b, so that the conductive heating element 320b is electrically conductive through the insulating sealing block 3104 arranged between the conductive electrode post 3106 and the connection base main body 3102, and meanwhile, condensate is reliably buffered in the buffering groove 321, meanwhile, the problem that condensate leaks out from the air inlet 312 is avoided, and the peripheral air flow is ensured to reliably enter the atomizing cavity 316 and the atomizing channel 322 through the air inlet 312 and the buffering groove 321. In this embodiment, the insulating sealing block is insulating silica gel or insulating rubber.
As shown in fig. 1 and 4, the conductive heating element 320b further includes a heating element main body 3202, a positive electrode conductive electrode 3204 and a negative electrode conductive electrode 3206, the heating element main body 3202 is wrapped on the oil guiding element 320a, the positive electrode conductive electrode 3204 and the negative electrode conductive electrode 3206 are respectively electrically connected with two ends of the heating element main body 3202, the positive electrode conductive electrode 3204 is electrically connected with the conductive electrode post 3106, the negative electrode conductive electrode 3206 is electrically connected with the connection base main body 3102, and the conductive heating element 320b is respectively electrically connected with the conductive electrode post 3106 and the connection base main body 3102.
The application also provides an electronic atomizing device comprising the atomizer 10 according to any one of the embodiments. Further, the atomizer 10 includes a sump assembly 100 and a heat generating assembly 300, the sump assembly 100 being detachably connected to the heat generating assembly 300 such that the sump assembly 100 can be replaced periodically. In this embodiment, the cartridge assembly 100 is used to store tobacco tar and the heater assembly 300 is used to heat the atomized tobacco tar. In one embodiment, the sump assembly 100 includes an oil cup 110, a sealing plug 120, and a movable plug 130. The oil cup 110 is provided with an oil storage cavity 112, a diversion channel 114 and a first oil inlet hole 116, and the oil storage cavity 112 is communicated with the diversion channel 114 through the first oil inlet hole 116. The oil cup 110 is detachably connected to the heat generating component 300, so that the heat generating component 300 is detachably connected to the oil sump component 100. The sealing plug 120 is located in the oil storage cavity 112 and elastically abuts against the oil cup 110 to seal the oil storage cavity 112, so that tobacco tar in the oil storage cavity 112 can only enter through the first oil inlet hole 116 when in use.
The movable plug 130 is located in the flow guiding channel 114 and elastically abuts against the oil cup 110, and the movable plug 130 is movably connected to the oil cup 110, so that the connection position between the movable plug 130 and the oil cup 110 is adjustable. The movable plug 130 is provided with an air passing hole 132 communicated with the diversion channel 114. The movable plug 130 is configured to be disposed corresponding to the first oil inlet 116 before use, so as to seal the first oil inlet 116. When the oil bin assembly 100 is connected with the heating assembly 300, the movable plug 130 abuts against the heating assembly 300 and moves to a position offset from the first oil inlet hole 116 relative to the oil cup 110, so that the tobacco tar can pass through the first oil inlet hole 116.
In one embodiment, the heat generating component 300 includes an atomization coupling mount 310 and an atomization member 320. The atomization connecting seat 310 is provided with an air inlet 312, a second oil inlet 314 and an atomization cavity 316, the air inlet 312 and the second oil inlet 314 are both communicated with the atomization cavity 316, and the atomization cavity 316 is communicated with the diversion channel 114. The atomization connecting seat 310 is detachably connected to the flow guiding channel 114, and abuts against and pushes the movable plug 130 to move relative to the oil cup 110 to a position where the first oil inlet 116 is communicated with the second oil inlet 314. In use, the atomization connecting seat 310 is completely inserted into the flow guiding channel 114, i.e. the atomization connecting seat 310 is assembled and connected in the flow guiding channel 114, the movable plug 130 moves relative to the oil cup 110 to a position where the first oil inlet 116 is communicated with the second oil inlet 314, and at this time, the first oil inlet 116 is communicated with the second oil inlet 314.
In one embodiment, the atomizer 320 is disposed in the atomization cavity 316 and connected to the atomization connecting base 310, and the outer peripheral wall of the atomizer 320 is disposed corresponding to the second oil inlet 314, so that the tobacco tar in the oil storage cavity 112 enters the atomization cavity 316 through the first oil inlet 116 and the second oil inlet 314 to contact with the atomizer 320, and the atomizer 320 is used for heating the tobacco tar to form atomized gas. The atomizing member 320 is provided with an atomizing channel 322, and the atomizing chamber 316 is respectively communicated with the air inlet 312 and the atomizing channel 322, so that the atomizing gas flows out through the atomizing channel 322, the atomizing chamber 316, the air passing hole 132 and the flow guiding channel 114 in sequence. In this embodiment, the atomization connecting base 310 abuts against the movable plug 130, so that the movable plug 130 is supported and limited by the atomization connecting base 310. The first oil inlet 116 is in opposite communication with the second oil inlet 314, so that the tobacco tar enters the atomization cavity 316 through the first oil inlet 116 and the second oil inlet 314.
According to the atomizer 10 of the electronic atomization device, the oil bin assembly 100 and the heating assembly 300 are detachably connected, namely the heating assembly 300 can be detached from the oil bin assembly 100 so as to be used for multiple times, before the electronic atomization device is used, the oil bin assembly 100 and the heating assembly 300 can be packaged and transported respectively, when the electronic atomization device is used, the oil bin assembly 100 is assembled with the heating assembly 300, the sealing plug 120 is positioned in the oil storage cavity 112 and elastically abuts against the oil cup 110 so as to seal the oil storage cavity 112, so that tobacco tar in the oil storage cavity 112 can only enter the first oil inlet 116, the movable plug 130 is positioned in the flow guide channel 114 and elastically abuts against the oil cup 110, the movable plug 130 can be movably connected to the oil cup 110, the relative connection position of the movable plug 130 and the oil cup 110 is adjustable, before the electronic atomization device is used, the piston is arranged corresponding to the first oil inlet 116 so as to seal the first oil inlet 116, and the tobacco tar in the oil storage cavity 112 cannot enter the flow guide channel 114 through the first oil inlet, namely the tobacco tar 120 and the movable plug 120 are arranged in the flow guide channel 114, the smoke bin assembly is easily, the smoke can be manufactured under the common action of the traditional oil cup assembly and the heating assembly 110, and the smoke can enter the oil bin assembly 100, compared with the traditional oil bin assembly 100, the whole structure is easily manufactured, and the smoke the whole structure is easily, and the cost is reduced, compared with the tobacco tar bin assembly 100 and the tobacco tar is manufactured, and the tobacco tar is easily, and the tobacco smoke in the whole structure is manufactured, and the tobacco smoke in the whole and has the tobacco smoke and the whole structure and has the tobacco smoke in the tobacco smoke and the tobacco smoke bin assembly and the smoke bin assembly.
Specifically, before use, the piston member is disposed corresponding to the first oil inlet hole 116 to seal the first oil inlet hole 116, so that the tobacco tar in the oil storage cavity 112 cannot enter the second oil inlet hole 314 and the atomization cavity 316 through the first oil inlet hole 116, and the oil path is in a non-conducting state, namely, under the combined action of the oil cup 110a, the center tube 110b, the movable plug 130 and the sealing plug 120, reliable transportation of the tobacco tar can be realized, the problem that the traditional oil bin assembly 100 is easy to leak oil in the transportation process is solved, when in use, the oil bin assembly 100 is connected with the atomization connecting seat 310, the movable plug 130 is abutted with the atomization connecting seat 310, and moves to a position staggered from the first oil inlet hole 116 relative to the oil cup 110a, so that the tobacco tar in the oil storage cavity 112 can enter the atomization cavity 316 through the first oil inlet hole 116 and the second oil inlet hole 314 to be atomized to form atomized gas, and the traditional electronic bin assembly 100 can be removed when the tobacco tar bin assembly 100 is used, namely, the traditional electronic bin assembly 100 is prevented from being replaced when the traditional electronic bin assembly 100 is used, and the traditional bin assembly 100 is completely, and the problem of using the electronic bin assembly is avoided.
Compared with the prior art, the invention has at least the following advantages:
1. According to the atomizer 10, as the heating component 300 is detachably connected with the oil cup 110, namely the oil bin component 100 is detachably connected with the heating component 300, the heating component 300 can be detached from the oil bin component 100 so as to be used for multiple times, before the atomizer is used, the oil bin component 100 and the heating component 300 can be packaged and transported respectively, as for the oil bin component 100, the movable plug 130 is positioned in the diversion channel and elastically abutted with the oil cup 110, and the movable plug 130 can be movably connected with the oil cup 110, before the atomizer is used, the movable plug 130 is positioned in the diversion channel and is correspondingly arranged with the first oil inlet, so that the movable plug 130 seals the first oil inlet, reliable transportation of tobacco tar is realized, the problem that oil is easy to leak in the transportation process of the traditional oil bin component 100 is solved;
2. When the smoke-absorbing device is used, the oil bin assembly 100 and the heating assembly 300 are assembled together, namely, the heating assembly 300 is assembled and connected with the oil cup 110, so that the heating assembly 300 is arranged corresponding to the first oil inlet hole, the movable plug 130 is staggered with the first oil inlet hole, smoke oil in the oil storage cavity enters the diversion channel through the first oil inlet hole to be abutted with the heating assembly 300, and the heating assembly 300 heats and atomizes the smoke oil to form atomized gas;
3. Because the oil bin assembly 100 is detachably connected with the heating assembly 300, when the tobacco tar in the oil storage cavity is used, namely, the tobacco tar in the oil cup 110 is used, the oil bin assembly 100 is replaced, that is, the oil bin assembly 100 is detached and can be reused, the oil bin assembly is convenient and quick, and meanwhile, the problem that the traditional oil bin assembly 100 and the heating assembly 300 are discarded together to cause the electronic atomization device to be poor in use environmental protection is avoided.
The above examples illustrate only a few embodiments of the invention, which are described in detail and are not to be construed as limiting the scope of the invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.