CN108308729B

CN108308729B - Non-combustion type tobacco smoking device based on PTC ceramic heating

Info

Publication number: CN108308729B
Application number: CN201810472839.3A
Authority: CN
Inventors: 房利鹏
Original assignee: Yancheng Zhaoyang Industrial Design Co Ltd
Current assignee: Shenzhen Kangweipu Technology Co ltd
Priority date: 2018-05-17
Filing date: 2018-05-17
Publication date: 2020-12-08
Anticipated expiration: 2038-05-17
Also published as: CN108308729A

Abstract

The invention discloses a non-combustion tobacco smoking device based on PTC ceramic heating, which structurally comprises a charging interface, an operation button, a display screen, a prompting lamp, an operation device, a contact port, an anti-skid friction layer and a disassembly port, and is characterized in that: the operation device comprises an atomization device, a pressing pushing device, a swinging pulling device, a new energy pushing group, a heat energy hydraulic rod device, an electric energy conversion device, a geothermal energy receiving device and a PTC ceramic heating group; the non-combustion tobacco suction device based on PTC ceramic heating can simultaneously use the function of PTC heating, and can be charged and stored with energy through the external condition while keeping the advantages of the PTC heating.

Description

Non-combustion type tobacco smoking device based on PTC ceramic heating

Technical Field

The invention relates to a PTC ceramic heating-based non-combustion type tobacco smoking device, belonging to the field of non-combustion type tobacco smoking devices.

Background

The electronic cigarette is an electronic product simulating a cigarette, has the same appearance, smoke, taste and feeling as the cigarette, is a product which is absorbed by a user after nicotine and the like are changed into steam by means of atomization and the like, and is specially researched by the world health organization, and a clear conclusion is drawn: the electronic cigarette is harmful to public health, is not a smoking cessation means, and must be controlled to avoid harm to teenagers and non-smokers.

However, in the prior art, more electronic cigarettes are heated by using the PTC, and due to the fact that the PTC heating block has no open fire, high safety, uniform heating and many advantages, the PTC heater is not only used for the electronic cigarettes, but also used for many household appliances, but also has high power consumption and low energy saving performance, and the PTC heater is troublesome in that the PTC heater is too fast in power consumption and is used for portable articles such as the electronic cigarettes.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a non-combustion tobacco smoking device based on PTC ceramic heating, so as to solve the problem that the existing electronic cigarette using PTC heating has more advantages due to the fact that a PTC heating block has no open fire, high safety, uniform heating, and high energy consumption, is not only used for the electronic cigarette, but also selected for a plurality of household appliances, but also has high PTC power consumption and low energy saving performance, and is troublesome when used for an article which can be carried about, such as the electronic cigarette.

In order to achieve the purpose, the invention is realized by the following technical scheme: a non-combustion tobacco smoking device based on PTC ceramic heating structurally comprises a charging interface, an operation button, a display screen, a prompting lamp, an operation device, a contact port, an anti-skid friction layer and a disassembly port,

the anti-skid friction layer is attached to the outer surface of the operation running device, the disassembly port is mounted on the outer surface of the operation running device, the display screen and the prompt lamp are mounted on the same plane, and the anti-skid friction layer is connected with the operation button through the operation running device;

the operation device comprises an atomization device, a pressing pushing device, a swinging pulling device, a new energy pushing group, a heat energy hydraulic rod device, an electric energy conversion device, a geothermal energy receiving device and a PTC ceramic heating group;

the atomizing device is arranged above the PTC ceramic heating unit, the pushing device is pressed and the swinging pulling device is connected, the new energy pushing unit is embedded and installed inside the heat energy hydraulic rod device, the heat energy hydraulic rod device is connected with the conversion electric energy device, the conversion electric energy device is installed above the geothermal energy receiving device, the swinging pulling device is connected with the conversion electric energy device, and the new energy pushing unit is arranged below the swinging pulling device.

Further, atomizing device includes the anti-overflow layer, puts oil check, dress oil entry, foam nickel, first conductor, first heat conductor, heater, ceramic seat, atomizer, removal seal piece, slide bar, insulator ring, export, it installs in anti-overflow in situ portion to put the embedding of oil check, dress oil entry is installed in putting oil check top, first conductor laminates in foam nickel internal surface, first heat conductor embedding is installed inside first conductor, the heater is connected with first conductor, ceramic seat installs in first conductor top, the atomizer is located the heater top, the slide bar embedding is installed inside removing seal piece, the insulator ring welds in the export bottom, press thrust unit and include first negative pole magnetic field, first positive magnetic field, gear, first pivot, slide bar, first slider, insection, first catch bar, Reset spring, second slider, second catch bar, second pivot, according to the briquetting, first negative pole magnetic field and first positive magnetic field are installed on the coplanar, first pivot embedding is installed in the gear and is located the same axle center, the slide bar embedding is installed inside first slider, the insection welds in first slider surface, first catch bar is connected with first slider, reset spring installs in according to the briquetting surface, the slide bar embedding is installed inside the second slider, the second catch bar is connected with the second slider, the embedding of second pivot is installed inside the second catch bar, the second pivot is installed inside according to the briquetting, the second slider is connected with swaying pulling device.

Further, sway the pulling device and include third pivot, third catch bar, fourth pivot, fourth catch bar, fifth catch bar, arc slide rail, propelling ball, first pull ring, first stay cord, the embedding of third pivot is installed inside the second slider, the third catch bar passes through third pivot and second slider hinged joint, the slide bar surface is located to the third catch bar, the fourth catch bar welds in fourth pivot surface, the fifth catch bar is connected with the fourth catch bar through the fourth pivot, the embedding of propelling ball is installed inside the arc slide rail, first pull ring welds in fifth catch bar surface, first stay cord is connected with first pull ring.

Further, the electric energy conversion device comprises a first friction electric conductor, a first joint rod, a fifth rotating shaft, a second friction electric conductor, a second joint rod, a sixth rotating shaft, a second conductor, a first protective insulating layer, a first PTC ceramic heating element, a first joint port, a conversion electric energy box, a seventh rotating shaft, a first fixing shaft, a block to be triggered, a reset spring, a second pull rope, a trigger block, a second joint port and a second heat conductor, wherein the first friction electric conductor is connected with the first joint rod, the first joint rod is welded on the outer surface of the fifth rotating shaft, the second friction electric conductor is arranged on the outer surface of the second joint rod and is connected with the sixth rotating shaft through the second joint rod, the second conductor is arranged on the rear surface of the sixth rotating shaft, the second conductor is embedded in the first protective insulating layer, the first PTC ceramic heating element is arranged in the first protective insulating layer, the first connection port is welded on the outer surface of the first protective insulating layer, the seventh rotating shaft is installed on the outer surface of the conversion electric energy box, the first fixing shaft is welded on the outer surface of the seventh rotating shaft, the trigger block is installed on the outer surface of the seventh rotating shaft, the reset spring is welded with the trigger block, the second pull rope is connected with the first fixing shaft, the second connection port is installed on the outer surface of the seventh rotating shaft, the second heat conductor is embedded and installed inside the first connection port, the conversion electric energy box is connected with the geothermal energy receiving device, and the second heat conductor is connected with the thermal energy hydraulic rod device.

Further, the PTC ceramic heating unit includes a third connection port, a storage battery, a negative electrode connection body, a first lead, a third conductor, a second pull ring, a positive electrode connection body, a third pull rope, a second fixing shaft, a second negative magnetic field, a second PTC ceramic heating element, a second protective insulating layer, an eighth rotating shaft, a fourth connection port, a third connection rod, and a second positive magnetic field, the third connection port is welded on the outer surface of the storage battery, the negative electrode connection body is installed on the outer surface of the storage battery, the third conductor is connected with the negative electrode connection body through the first lead, the second pull ring is welded on the outer surface of the third conductor, the positive electrode connection body is installed on the outer side of the storage battery, the third pull rope is connected with the second pull ring, the third pull rope is installed on the outer surface of the second fixing shaft, the second fixing shaft is welded on the outer surface of the eighth rotating shaft, the third connection rod is, the second PTC ceramic heating element is embedded in the second protective insulating layer, the fourth connection port is welded on the outer surface of the second protective insulating layer, the third connection rod is connected with a second positive magnetic field, the storage battery is installed on the upper surface of the geothermal energy receiving device, the geothermal energy receiving device comprises a second wire, a heat absorption layer, an energy transfer block, a conductive layer and a fifth connection port, the second wire is connected with the energy transfer block, the heat absorption layer is parallel to the conductive layer, the fifth connection port is installed on the outer surface of the top of the conductive layer, the energy transfer block is arranged above the heat absorption layer, the fifth connection port is welded on the outer surface of the bottom of the conversion electric energy box, the storage battery is installed on the outer surface of the top of the conductive layer, the conversion electric energy box is electrically connected with the conductive layer through the wire, and the third connection port is.

Further, the heat energy hydraulic rod device comprises a third friction conductor, a third lead, a fourth joint, a conductive layer, a protective layer, a low-temperature slideway, a first sliding block, a sliding rod, a ninth rotating shaft, a fixing frame, a fixing block, a second sliding block, a hot air slideway and a fourth friction conductor, wherein the third friction conductor is arranged below the conductive layer, the third lead is embedded in the fourth joint, the conductive layer is attached to the protective layer, the first sliding block is embedded in the low-temperature slideway, the ninth rotating shaft is connected with the first sliding block, the sliding rod is embedded in the first sliding block, the sliding rod is arranged in the fixing frame, the fixing block is welded with the sliding rod, the sliding rod is embedded in the second sliding block, the second sliding block is arranged in the hot air slideway, and the fourth friction conductor is welded on the outer surface of the top of the second sliding block, the second heat conductor is embedded in the hot gas slide way, and a first protective insulating layer is arranged below the hot gas slide way.

Furthermore, the new energy pushing group comprises a tenth rotating shaft, a sixth pushing rod, an eleventh rotating shaft, fan blades, a conveying belt, a twelfth rotating shaft, a blowing opening, a seventh pushing rod, an eighth pushing rod, a ninth pushing rod, a thirteenth rotating shaft, a tenth pushing rod and a fourteenth rotating shaft, the tenth rotating shaft is embedded in the sixth pushing rod and connected with the eleventh rotating shaft through the sixth pushing rod, the fan blades are welded on the outer surface of the twelfth rotating shaft, the transmission belt is arranged on the outer surface of the twelfth rotating shaft, the blowing opening is arranged at the side of the twelfth rotating shaft, the seventh push rod is hinged with the ninth push rod, the ninth push rod is connected with the tenth push rod through a thirteenth rotating shaft, the fourteenth rotating shaft is embedded and installed inside the tenth push rod, the thirteenth rotating shaft is installed inside the ninth push rod, and the eleventh rotating shaft is installed inside the eighth push rod in an embedded manner.

Advantageous effects

The invention relates to a PTC ceramic heating-based non-combustion tobacco suction device, tobacco tar is injected into an oil containing grid from an oil containing inlet, a pressing block is pressed by external force, so that a return spring of the compression block is extruded, a first pushing rod and a second pushing rod drive a first sliding block and a second sliding block to slide along a sliding rod to two sides and slide along an arc-shaped sliding rail, a fourth pushing rod is touched during sliding, a first pull rope on a first pull ring is driven to run together when a fifth pushing rod starts to rotate, a first fixed shaft and a trigger block are driven to rotate, when the fifth pushing rod rotates to a certain position, the trigger block and a block to be triggered are installed together, a conversion electric energy box is started through the contact of the fourth pushing rod and the fifth pushing rod, a first negative magnetic field and a first positive magnetic field which are installed on a gear rotate along with the first positive magnetic field, and a second negative magnetic field and a second positive magnetic field are pushed to rotate by the mutual repulsive force of the same magnetic field while the trigger block rotates, the third conductor is pulled to slide to be in contact with the anode connector, the cathode connector is connected with the first conductor through the first lead and is electrified, after the electrification, the electric energy is led into the second PTC ceramic heating element to be heated, the ceramic base above the second conductor is heated more uniformly, the outlet of the second conductor is sucked through the outside, so that the movable sealing block is sucked upwards through suction force to slide to the top along the sliding rod, the oil in the oil grid is placed on the movable sealing block, the movable sealing block enters the atomizer through heating and then is sucked out from the outlet, when the movable sealing block is not electrified and is inconvenient to be electrified, the movable sealing block can be placed at a geothermal position or a windy position, the fan blades are blown through wind power, the twelfth rotating shaft is driven to rotate together to generate the electric energy, the electric energy is led into the first PTC ceramic heating element through the second conductor to be heated, the heat energy is led into the slideway through the second heat conductor, the air in the low-temperature slideway is heated, so that the first sliding block in the low-temperature slideway enables a seventh push rod to assist the sliding rod to slide back and forth on the sliding rod under the action of force of heat and cold contraction, when the second sliding block slides back and forth, a fourth friction conductor and a third friction conductor are driven to rub to generate electric energy, the electric energy is guided into a conversion electric energy box through a third lead to be converted and stored, if geothermal energy exists, the electric energy is sucked through the contact of a heat absorption layer and is guided into an energy conversion block, and then the electric energy is transmitted into a conductive layer and is converted and stored by the electric energy conversion electric energy box;

the non-combustion tobacco smoking device based on PTC ceramic heating can simultaneously use the PTC heating function and retain the advantages of the PTC heating function, and meanwhile, the PTC heating device is added with the function of converting new energy into electric energy, so that the PTC which consumes more power can be charged and stored with energy through the external condition when the PTC is out of the environment if no power is supplied.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

FIG. 1 is a schematic structural view of a non-combustion tobacco smoking device based on PTC ceramic heating according to the present invention;

FIG. 2 is a schematic diagram of an internal structure of an operation device according to the present invention;

FIG. 3 is a schematic view of the internal structure of an operation device according to the present invention;

FIG. 4 is a schematic diagram of the internal structure of an operation device according to the present invention;

FIG. 5 is a schematic diagram of the internal structure of an apparatus for converting electric energy according to the present invention;

FIG. 6 is a schematic view of the internal structure of a thermal energy hydraulic rod apparatus according to the present invention;

fig. 7 is a schematic diagram of an internal structure of a new energy propulsion group according to the present invention.

In the figure: a charging interface-1, an operation button-2, a display screen-3, a prompting lamp-4, an operation running device-5, a contact port-6, an anti-skid friction layer-7, a disassembly port-8, an atomization device-51, a pressing pushing device-52, a swing pulling device-53, a new energy pushing group-54, a thermal energy hydraulic rod device-55, a conversion electric energy device-56, a geothermal energy receiving device-57, a PTC ceramic heating group-58, an anti-overflow layer-511, an oil containing grid-512, an oil containing inlet-513, a foam nickel-514, a first conductor-515, a first heat conductor-516, a heating wire-517, a ceramic seat-518, an atomizer-519, a movable sealing block-5110, a sliding rod-5111, an insulating ring-5112, an operation running device-5, a contact port-6, an anti-skid friction layer-7, an outlet-5113, a first negative magnetic field-521, a first positive magnetic field-522, a gear-523, a first rotating shaft-524, a sliding rod-525, a first sliding block-526, a tooth pattern-527, a first push rod-528, a return spring-529, a second sliding block-5210, a second push rod-5211, a second rotating shaft-5212, a pressing block-5213, a third rotating shaft-531, a third push rod-532, a fourth rotating shaft-533, a fourth push rod-534, a fifth push rod-535, an arc sliding rail-536, a push ball-537, a first pull ring-538, a first pull rope-539, a first friction conductor-561, a first connecting rod-562, a fifth rotating shaft-563, a second friction conductor-564, a second connecting rod-565, A sixth rotating shaft-566, a second conductor-567, a first protective insulating layer-568, a first PTC ceramic heating element-569, a first connecting port-5610, a conversion electric energy box-5611, a seventh rotating shaft-5612, a first fixed shaft-5613, a block-5614 to be triggered, a reset spring-5615, a second pull rope-5616, a triggering block-5617, a second connecting port-5618, a second heat conductor-5619, a third connecting port-581, a storage battery-582, a negative electrode connector-583, a first lead-584, a third conductor-585, a second pull ring-586, a positive electrode connector-587, a third pull rope-588, a second fixed shaft-589, a second negative electrode magnetic field-5810, a second PTC ceramic heating element-5811, a second protective insulating layer-5812, An eighth rotating shaft-5813, a fourth joint-5814, a third joint rod-5815, a second positive magnetic field-5816, a geothermal energy receiving device-57 comprising a second lead-571, a heat absorbing layer-572, a transduction block-573, a conductive layer-574, a fifth joint-575, a third frictional conductor-551, a third lead-552, a fourth joint-553, a conductive layer-554, a protective layer-555, a low temperature slide-556, a first slide-557, a slide-558, a ninth rotating shaft-559, a fixing frame-5510, a fixing block-5511, a second slide-5512, a hot gas slide-5513, a fourth conductive friction-5514, a tenth rotating shaft-541, a sixth push rod-542, an eleventh rotating shaft-543, a fan blade-544, a fan blade-5512, a fan blade-553, a fan blade, A transmission belt-545, a twelfth rotating shaft-546, a blowing opening-547, a seventh push rod-548, an eighth push rod-549, a ninth push rod-5410, a thirteenth rotating shaft-5411, a tenth push rod-5412 and a fourteenth rotating shaft-5413.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

Referring to fig. 1, 2, 3, 4, 5, 6 and 7, the present invention provides a technical solution of a non-combustion type tobacco smoking device based on PTC ceramic heating: the structure of the device comprises a charging interface 1, an operating button 2, a display screen 3, a prompting lamp 4, an operating device 5, a contact port 6, an anti-skid friction layer 7 and a disassembly port 8,

the charging interface 1 is embedded in the operation running device 5, the operation button 2 is installed in the operation running device 5, the display screen 3 is in clearance fit with the operation running device 5, the prompt lamp 4 is embedded in the operation running device 5, the contact port 6 is arranged above the operation running device 5, the anti-skid friction layer 7 is attached to the outer surface of the operation running device 5, the disassembly port 8 is installed on the outer surface of the operation running device 5, the display screen 3 and the prompt lamp 4 are installed on the same plane, and the anti-skid friction layer 7 is connected with the operation button 2 through the operation running device 5;

the operation device 5 comprises an atomization device 51, a pressing pushing device 52, a swinging pulling device 53, a new energy pushing group 54, a thermal energy hydraulic rod device 55, a conversion electric energy device 56, a geothermal energy receiving device 57 and a PTC ceramic heating group 58;

the atomization device 51 is arranged above the PTC ceramic heating group 58, the pressing pushing device 52 is connected with the swinging pulling device 53, the new energy pushing group 54 is embedded in the heat energy hydraulic rod device 55, the heat energy hydraulic rod device 55 is connected with the electric energy conversion device 56, the electric energy conversion device 56 is arranged above the geothermal energy receiving device 57, the swinging pulling device 53 is connected with the electric energy conversion device 56, and the new energy pushing group 54 is arranged below the swinging pulling device 53.

Atomizing device 51 includes anti-overflow layer 511, puts oil check 512, oil filling entry 513, foam nickel 514, first conductor 515, first heat conductor 516, heater 517, pottery seat 518, atomizer 519, removal seal block 5110, slide bar 5111, insulating ring 5112, export 5113, it installs inside anti-overflow layer 511 to put the embedding of oil check 512, oil filling entry 513 is installed in putting oil check 512 top, first conductor 515 laminates in foam nickel 514 internal surface, first heat conductor 516 embedding is installed inside first conductor 515, heater 517 is connected with first conductor 515, pottery seat 518 is installed in first conductor 515 top, atomizer 519 locates heater 517 top, slide bar 5111 embedding is installed inside removal seal block 5110, insulating ring 5112 welds in export 5113 bottom, press thrust unit 52 to include first negative pole magnetic field 521, first positive pole magnetic field 522, a, The magnetic field generating device comprises a gear 523, a first rotating shaft 524, a sliding rod 525, a first sliding block 526, a insection 527, a first pushing rod 528, a return spring 529, a second sliding block 5210, a second pushing rod 5211, a second rotating shaft 5212 and a pressing block 5213, wherein the first negative magnetic field 521 and the first positive magnetic field 522 are installed on the same plane, the first rotating shaft 524 is embedded in the gear 523 and positioned on the same axis, the sliding rod 525 is embedded in the first sliding block 526, the insection 527 is welded on the outer surface of the first sliding block 526, the first pushing rod 528 is connected with the first sliding block 526, the return spring 529 is installed on the outer surface of the pressing block 5213, the sliding rod 525 is embedded in the second sliding block 5210, the second pushing rod 5211 is connected with the second sliding block 5210, the second rotating shaft 5212 is embedded in the second pushing rod 5211, and the second rotating shaft 5212 is installed in the pressing block 5213, the second slider 5210 is connected to the rocking pulling means 53.

The swing pulling device 53 includes a third rotating shaft 531, a third push rod 532, a fourth rotating shaft 533, a fourth push rod 534, a fifth push rod 535, an arc-shaped sliding rail 536, a push ball 537, a first pulling ring 538 and a first pulling rope 539, the third rotating shaft 531 is embedded in the second sliding block 5210, the third push rod 532 is hinged to the second sliding block 5210 through the third rotating shaft 531, the third push rod 532 is disposed on the outer surface of the sliding rod 525, the fourth push rod 534 is welded to the outer surface of the fourth rotating shaft 533, the fifth push rod 535 is connected to the fourth push rod 534 through the fourth rotating shaft 533, the push ball 537 is embedded in the arc-shaped sliding rail 536, the first pulling ring 538 is welded to the outer surface of the fifth push rod 535, and the first pulling rope 539 is connected to the first pulling ring 538.

The electric energy conversion device 56 comprises a first frictional conductor 561, a first joint rod 562, a fifth rotating shaft 563, a second frictional conductor 564, a second joint rod 565, a sixth rotating shaft 566, a second conductor 567, a first protective insulating layer 568, a first PTC ceramic heating element 569, a first joint 5610, an electric energy conversion box 5611, a seventh rotating shaft 5612, a first fixed shaft 5613, a block to be triggered 5614, a reset spring 5615, a second pull rope 5616, a trigger block 5617, a second joint 5618 and a second heat conductor 5619, wherein the first frictional conductor 561 is connected with the first joint rod 562, the first joint rod 562 is welded on the outer surface of the fifth rotating shaft 563, the second frictional conductor 564 is mounted on the outer surface of the second joint rod 565, the second frictional conductor 564 is connected with the sixth rotating shaft 566 through the second joint rod 565, the second conductor 567 is mounted on the rear surface of the sixth rotating shaft 566, and the second conductor 567 is embedded in the first protective insulating layer 568, the first PTC ceramic heater 569 is installed inside the first protective insulating layer 568, the first engagement port 5610 is welded to the outer surface of the first protective insulating layer 568, the seventh rotation shaft 5612 is installed on the outer surface of the conversion electric energy box 5611, the first fixing shaft 5613 is welded to the outer surface of the seventh rotation shaft 5612, the block to be triggered 5614 is installed on the outer surface of the seventh rotation shaft 5612, the return spring 5615 is welded to the trigger 5617, the second pull rope 5616 is connected to the first fixing shaft 5613, the second engagement port 5618 is installed on the outer surface of the seventh rotation shaft 5612, the second heat conductor 5619 is embedded inside the first engagement port 5610, the conversion electric energy box 5611 is connected to the geothermal energy receiving device 57, and the second heat conductor 5619 is connected to the thermal energy hydraulic rod device 55.

The PTC ceramic heating group 58 comprises a third joint port 581, a storage battery 582, a negative electrode connector 583, a first lead 584, a third conductor 585, a second pull ring 586, a positive electrode connector 587, a third pull rope 588, a second fixed shaft 589, a second negative magnetic field 5810, a second PTC ceramic heating element 5811, a second protective insulating layer 5812, an eighth rotating shaft 5813, a fourth joint port 5814, a third joint rod 5815 and a second positive magnetic field 5816, wherein the third joint port 581 is welded on the outer surface of the storage battery 582, the negative electrode connector 583 is installed on the outer surface of the storage battery 582, the third conductor 585 is connected with the negative electrode connector 583 through the first lead 584, the second pull ring 586 is welded on the outer surface of the third conductor 585, the positive electrode connector 587 is installed on the outer side of the storage battery 582, the third pull rope 588 is connected with the second pull ring 586, the third pull rope 588 is installed on the outer surface of the second fixed shaft 589, the second fixed shaft 589 is welded to the outer surface of the eighth rotating shaft 5813, the third connecting rod 5815 is connected to a second negative magnetic field 5810, the second PTC ceramic heater 5811 is embedded in the second protective insulating layer 5812, the fourth connecting port 5814 is welded to the outer surface of the second protective insulating layer 5812, the third connecting rod 5815 is connected to a second positive magnetic field 5816, the battery 582 is installed on the upper surface of the geothermal energy receiving device 57, the geothermal energy receiving device 57 includes a second conducting wire 571, a heat absorbing layer 572, a rotation block 573, a conducting layer 574, a fifth connecting port 575, the second conducting wire 571 is connected to a rotation block 573, the heat absorbing layer 572 and the conducting layer 574 are parallel to each other, the fifth connecting port 575 is installed on the outer surface of the top of the conducting layer 574, the rotation block 573 is installed above the heat absorbing layer 572, the fifth connecting port 575 is welded to the outer surface of the bottom of the electric energy conversion box 5611, the storage battery 582 is installed on the top outer surface of the conductive layer 574, the conversion power box 5611 is electrically connected with the conductive layer 574 through a lead, and the third connecting port 581 is arranged above the heat absorbing layer 572.

The thermal hydraulic rod device 55 comprises a third frictional conductor 551, a third wire 552, a fourth seam 553, a conductive layer 554, a protective layer 555, a low-temperature slideway 556, a first sliding block 557, a sliding rod 558, a ninth rotating shaft 559, a fixed frame 5510, a fixed block 5511, a second sliding block 5512, a hot gas slideway 5513 and a fourth frictional conductor 5514, wherein the third frictional conductor 551 is installed below the conductive layer 554, the third wire 552 is embedded and installed inside the fourth seam 553, the conductive layer 554 is attached to the protective layer 555, the first sliding block 557 is embedded and installed inside the low-temperature slideway 556, the ninth rotating shaft 559 is connected to the first sliding block 557, the sliding rod 558 is embedded and installed inside the first sliding block 557, the sliding rod 558 is installed inside the fixed frame 5510, the fixed block 5511 is welded to the sliding rod 558, the sliding rod 558 is embedded and installed inside the second sliding block 5512, the second slider 5512 is installed inside the hot gas slide 5513, the fourth frictional conductor 5514 is welded on the outer surface of the top of the second slider 5512, the second heat conductor 5619 is embedded inside the hot gas slide 5513, and a first protective insulating layer 568 is arranged below the hot gas slide 5513.

The new energy pushing group 54 includes a tenth rotation shaft 541, a sixth pushing rod 542, an eleventh rotation shaft 543, fan blades 544, a transmission belt 545, a twelfth rotation shaft 546, a blowing opening 547, a seventh pushing rod 548, an eighth pushing rod 549, a ninth pushing rod 5410, a thirteenth rotation shaft 5411, a tenth pushing rod 5412, and a fourteenth rotation shaft 5413, the tenth rotation shaft 541 is embedded in the sixth pushing rod 542, the tenth rotation shaft 541 is connected with the eleventh rotation shaft 543 through the sixth pushing rod 542, the fan blades 544 are welded on the outer surface of the twelfth rotation shaft 546, the transmission belt 545 is installed on the outer surface of the twelfth rotation shaft 546, the blowing opening 547 is arranged on the side of the twelfth rotation shaft 546, the seventh pushing rod 548 is hinged with the ninth pushing rod 5410, the ninth pushing rod 5410 is connected with the tenth pushing rod 5412 through the thirteenth rotation shaft 5411, and the fourteenth rotation shaft 5413 is embedded in the tenth pushing rod 5412, the thirteenth rotating shaft 5411 is installed inside the ninth pushing rod 5410, and the eleventh rotating shaft 543 is embedded inside the eighth pushing rod 549.

The first PTC ceramic heating element 569PTC heating element is called PTC heater, it is made up of PTC ceramic heating element and aluminium tube, this type of PTC heating element has the advantages of small thermal resistance and high heat exchange efficiency, it is an automatic constant temperature and electricity saving electric heater, the outstanding characteristic lies in that on the safety performance, the surface of the electric heating tube heater will not be "red" in any application situation, thereby the potential safety hazard such as scald, fire hazard, etc. is caused, the insulating ring 5112 insulating material is a non-conductive material under the allowable voltage, but not an absolutely non-conductive material, under the action of certain external electric field intensity, the processes such as conduction, polarization, loss, breakdown, etc. can also take place, and the long-term use can also take place the ageing.

When the oil smoke sucking device is used, oil smoke is injected into the oil containing grid 512 from the oil inlet 513, the pressing block 5213 is pressed by external force, so that the return spring 529 is pressed, the first push rod 528 and the second push rod 5211 drive the first slider 526 and the second slider 5210 to slide along the sliding rod 525 to two sides, when the second slider 5210 slides, the third rotating shaft 531 mounted on the outer surface is driven to operate together, the third push rod 532 is pressed, the push ball 537 slides along the arc-shaped sliding rail 536 by the pressing force, the fourth push rod 534 is touched during sliding, so that the fourth push rod 534 is driven to rotate along the fourth rotating shaft 533, the fifth push rod 535 also rotates along with the fifth rotating shaft to abut against the rear of the push ball 537, when the fifth push rod 535 starts to rotate, the first pull rope 539 on the first pull ring 538 is driven to operate together, and the pull force of the rope is passed, the first fixed shaft 5613 and the trigger block 5617 are driven to rotate, so that the trigger block 5617 presses the return spring 5615, when the trigger block 5617 rotates to a certain position, the trigger block 5617 is mounted with the block 5614 to be triggered, the conversion electric energy box 5611 is started through the contact between the trigger block and the block 5614, the internal electric energy is led into the storage battery 582 through the third connecting port 581, the first sliding block 526 drives the gear 523 to rotate through the insections 527 in the sliding process, the first negative magnetic field 521 and the first positive magnetic field 522 mounted on the gear 523 rotate along with the first negative magnetic field, when the first sliding block 526 rotates, the second negative magnetic field 5810 and the second positive magnetic field 5816 are pushed by the mutual repulsive force of the same magnetic fields to rotate along with the first positive magnetic field, the eighth rotating shaft 5813 is driven through the third connecting rod 5815, so that the second fixed shaft 589 mounted on the first fixed shaft is driven, and the second fixed shaft 589 pulls the third pull rope 588 when the second fixed, the third conductor 585 is pulled to slide to contact with the positive connector 587, the negative connector 583 is connected with the first lead 584 to be electrified, electric energy is led into the second PTC ceramic heater 5811 after electrification, the second PTC ceramic heater starts to be heated, heat energy is led to the first conductor 515 through the first heat conductor 516 and is transmitted to the heating wire 517, the heating wire is heated more uniformly through the upper ceramic seat 518, the outlet 5113 is sucked through the outside, the movable sealing block 5110 is sucked upwards through suction to slide to the top along the sliding rod 5111, oil in the oil compartment 512 is placed in the atomizer 519 through heating, the oil is sucked out from the outlet 5113, when the third conductor is not electrified and is inconvenient to electrify, the third conductor can be placed at a position of geothermal heat or a position of wind, the twelfth rotating shaft 546 is driven to rotate through blowing 544 by wind power, and when the third conductor rotates, the fifth rotating shaft 563 is driven to rotate through the transmission belt 545, thereby driving the first frictional conductor 561, when it is rotated to a certain position, it will touch the second frictional conductor 564 to impact it and drive it to rotate together, generating electric energy, leading the electric energy into the first PTC ceramic heater 569 through the second conductor 567 to heat after passing through it, leading the heat energy into the hot gas slideway 5513 through the second conductor 5619 to heat the air inside it, pushing the second slider 5512 backwards through thermal expansion and contraction, thereby pushing the sliding rod 558, making the first sliding block 557 inside the low temperature slideway 556 through the force of thermal expansion and contraction, making the seventh pushing rod 548 assist it to slide on the sliding rod 558 back and forth, when the second sliding block 5512 slides back and forth, it will drive the fourth frictional conductor 5514 to rub against the third frictional conductor 551 to generate electric energy, leading it into the conversion electric energy box 5611 through the third conducting wire 552 to convert and store, if there is heat, the heat energy is absorbed by the contact of the heat absorbing layer 572 and is guided into the energy conversion block 573, so that the heat energy is transmitted into the conductive layer 574, and the electric energy is transmitted into the electric energy conversion box 5611 to be converted and stored.

The invention solves the problems that the existing electronic cigarette heated by PTC has more advantages, no open fire, higher safety, uniform heating and more advantages, is not only used for the electronic cigarette, but also selected for a plurality of household appliances, has higher PTC power consumption and lower energy-saving property, and has trouble when power is consumed too fast like being used for an electronic cigarette which can be carried about.

While there have been shown and described what are at present considered the fundamental principles and essential features of the invention and its advantages, it will be apparent to those skilled in the art that the invention is not limited to the details of the foregoing exemplary embodiments, but is capable of other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims

1. The utility model provides a non-combustion type tobacco smoking device based on PTC ceramic heating, its structure includes interface (1) that charges, operating button (2), display screen (3), warning light (4), operation running device (5), contact port (6), anti-skidding frictional layer (7), dismantlement port (8), its characterized in that:

the charging interface (1) is embedded in the operation running device (5), the operation button (2) is installed in the operation running device (5), the display screen (3) is in clearance fit with the operation running device (5), the prompt lamp (4) is embedded in the operation running device (5), the contact port (6) is arranged above the operation running device (5), the anti-skid friction layer (7) is attached to the outer surface of the operation running device (5), the disassembly port (8) is installed on the outer surface of the operation running device (5), the display screen (3) and the prompt lamp (4) are installed on the same plane, and the anti-skid friction layer (7) is connected with the operation button (2) through the operation running device (5);

the operation device (5) comprises an atomization device (51), a pressing pushing device (52), a swinging pulling device (53), a new energy pushing group (54), a thermal energy hydraulic rod device (55), a conversion electric energy device (56), a geothermal energy receiving device (57) and a PTC ceramic heating group (58);

the atomization device (51) is arranged above the PTC ceramic heating group (58), the pressing pushing device (52) is connected with the swinging pulling device (53), the new energy pushing group (54) is embedded and installed inside the heat energy hydraulic rod device (55), the heat energy hydraulic rod device (55) is connected with the electric energy conversion device (56), the electric energy conversion device (56) is installed above the geothermal energy receiving device (57), the swinging pulling device (53) is connected with the electric energy conversion device (56), and the new energy pushing group (54) is arranged below the swinging pulling device (53);

the atomizing device (51) comprises an anti-overflow layer (511), an oil containing grid (512), an oil containing inlet (513), foam nickel (514), a first conductor (515), a first heat conductor (516), a heating wire (517), a ceramic seat (518), an atomizer (519), a movable sealing block (5110), a sliding rod (5111), an insulating ring (5112) and an outlet (5113), wherein the oil containing grid (512) is embedded in the anti-overflow layer (511), the oil containing inlet (513) is arranged above the oil containing grid (512), the first conductor (515) is attached to the inner surface of the foam nickel (514), the first heat conductor (516) is embedded in the first conductor (515), the heating wire (517) is connected with the first conductor (515), the ceramic seat (518) is arranged above the first conductor (515), and the atomizer (519) is arranged above the heating wire (517), the sliding rod (5111) is embedded and installed inside the movable sealing block (5110), and the insulating ring (5112) is welded at the bottom of the outlet (5113);

the pressing pushing device (52) comprises a first negative pole magnetic field (521), a first positive pole magnetic field (522), a gear (523), a first rotating shaft (524), a sliding rod (525), a first sliding block (526), insections (527), a first pushing rod (528), a reset spring (529), a second sliding block (5210), a second pushing rod (5211), a second rotating shaft (5212) and a pressing block (5213), wherein the first negative pole magnetic field (521) and the first positive pole magnetic field (522) are installed on the same plane, the first rotating shaft (524) is installed inside the gear (523) in an embedded mode and located on the same axis, the sliding rod (525) is installed inside the first sliding block (526) in an embedded mode, the insections (527) are welded on the outer surface of the first sliding block (526), the first pushing rod (528) is connected with the first sliding block (526), and the reset spring (529) is installed on the outer surface of the pressing block (5213), the sliding rod (525) is embedded in a second sliding block (5210), the second push rod (5211) is connected with the second sliding block (5210), the second rotating shaft (5212) is embedded in the second push rod (5211), the second rotating shaft (5212) is installed in a pressing block (5213), and the second sliding block (5210) is connected with the swinging pulling device (53);

the swing pulling device (53) comprises a third rotating shaft (531), a third push rod (532), a fourth rotating shaft (533), a fourth push rod (534), a fifth push rod (535), an arc-shaped sliding rail (536), a push ball (537), a first pull ring (538) and a first pull rope (539), wherein the third rotating shaft (531) is embedded in a second sliding block (5210), the third push rod (532) is hinged with the second sliding block (5210) through the third rotating shaft (531), the third push rod (532) is arranged on the outer surface of the sliding rod (525), the fourth push rod (534) is welded on the outer surface of the fourth rotating shaft (533), the fifth push rod (535) is connected with the fourth push rod (534) through the fourth rotating shaft (533), the push ball (537) is embedded in the arc-shaped sliding rail (536), the first pull ring (538) is welded on the outer surface of the fifth push rod (535), the first pull rope (539) is connected with a first pull ring (538);

the electric energy conversion device (56) comprises a first frictional conductor (561), a first connecting rod (562), a fifth rotating shaft (563), a second frictional conductor (564), a second connecting rod (565), a sixth rotating shaft (566), a second conductor (567), a first protective insulating layer (568), a first PTC ceramic heating body (569), a first connecting port (5610), an electric energy conversion box (5611), a seventh rotating shaft (5612), a first fixed shaft (5613), a block to be triggered (5614), a reset spring (5615), a second pull rope (5616), a trigger block (5617), a second connecting port (5618) and a second heat conductor (5619), wherein the first frictional conductor (561) is connected with the first connecting rod (562), the first connecting rod (562) is welded on the outer surface of the fifth rotating shaft (563), and the second frictional conductor (564) is installed on the outer surface of the second connecting rod (565), the second friction conductor (564) is connected with a sixth rotating shaft (566) through a second engagement rod (565), the second conductor (567) is installed on the rear surface of the sixth rotating shaft (566), the second conductor (567) is embedded and installed inside a first protective insulating layer (568), the first PTC ceramic heating element (569) is installed inside the first protective insulating layer (568), the first engagement port (5610) is welded on the outer surface of the first protective insulating layer (568), the seventh rotating shaft (5612) is installed on the outer surface of a conversion power box (5611), the first fixing shaft (5613) is welded on the outer surface of the seventh rotating shaft (5612), the block to be triggered (5614) is installed on the outer surface of the seventh rotating shaft (5612), the reset spring (15) is welded with the trigger block (5617), the second pull rope (5616) is connected with the first fixing shaft (5613), and the second engagement port (5618) is installed on the outer surface of the seventh rotating shaft (5612), the second heat conductor (5619) is embedded and installed inside the first connecting port (5610), the conversion electric energy box (5611) is connected with the geothermal energy receiving device (57), and the second heat conductor (5619) is connected with the thermal energy hydraulic rod device (55);

the PTC ceramic heating group (58) comprises a third joint (581), a storage battery (582), a negative electrode connector (583), a first lead (584), a third conductor (585), a second pull ring (586), a positive electrode connector (587), a third pull rope (588), a second fixed shaft (589), a second negative magnetic field (5810), a second PTC ceramic heating element (5811), a second protective insulating layer (5812), an eighth rotating shaft (5813), a fourth joint (5814), a third joint rod (5815) and a second positive magnetic field (5816), wherein the third joint (581) is welded on the outer surface of the storage battery (582), the negative electrode connector (583) is installed on the outer surface of the storage battery (582), the third conductor (585) is connected with the negative electrode connector (583) through the first lead (584), and the second conductor (586) is welded on the outer surface of the third conductor (585), the positive connector (587) is installed in the outside of a storage battery (582), the third pull rope (588) is connected with the second pull ring (586), the third pull rope (588) is installed on the outer surface of a second fixed shaft (589), the second fixed shaft (589) is welded on the outer surface of an eighth rotating shaft (5813), the third connecting rod (5815) is connected with a second negative pole magnetic field (5810), the second PTC ceramic heating element (5811) is embedded in a second protective insulating layer (5812), the fourth connecting port (5814) is welded on the outer surface of a second protective insulating layer (5812), the third connecting rod (5815) is connected with a second positive pole magnetic field (5816), and the storage battery (582) is installed on the upper surface of the geothermal energy receiving device (57).

2. A non-combustible tobacco smoking device based on PTC ceramic heating according to claim 1, wherein: the geothermal energy receiving device (57) comprises a second lead (571), a heat absorption layer (572), an energy conversion block (573), a conductive layer (574) and a fifth connection port (575), wherein the second lead (571) is connected with the energy conversion block (573), the heat absorption layer (572) is parallel to the conductive layer (574), the fifth connection port (575) is installed on the outer surface of the top of the conductive layer (574), the energy conversion block (573) is arranged above the heat absorption layer (572), the fifth connection port (575) is welded on the outer surface of the bottom of a conversion electric energy box (5611), a storage battery (582) is installed on the outer surface of the top of the conductive layer (574), the conversion electric energy box (5611) is electrically connected with the conductive layer (574) through a lead, and the third connection port (581) is arranged above the heat absorption layer (572).

3. A non-combustible tobacco smoking device based on PTC ceramic heating according to claim 2, wherein: the thermal energy hydraulic rod device (55) comprises a third friction conductor (551), a third lead (552), a fourth connecting port (553), a conductive layer (554), a protective layer (555), a low-temperature slideway (556), a first sliding block (557), a sliding rod (558), a ninth rotating shaft (559), a fixing frame (5510), a fixing block (5511), a second sliding block (5512), a hot air slideway (5513) and a fourth friction conductor (5514), wherein the third friction conductor (551) is installed below the conductive layer (554), the third lead (552) is embedded and installed inside the fourth connecting port (553), the conductive layer (554) is attached to the protective layer (555), the first sliding block (557) is embedded and installed inside the low-temperature slideway (556), the ninth rotating shaft (559) is connected with the first sliding block (557), the sliding rod (558) is embedded and installed inside the first sliding block (557), the sliding rod (558) is installed inside the fixed frame (5510), the fixed block (5511) is welded with the sliding rod (558), the sliding rod (558) is installed inside the second sliding block (5512) in an embedded mode, the second sliding block (5512) is installed inside the hot gas slide way (5513), the fourth friction conductor (5514) is welded on the outer surface of the top of the second sliding block (5512), the second heat conductor (5619) is installed inside the hot gas slide way (5513) in an embedded mode, and a first protective insulating layer (568) is arranged below the hot gas slide way (5513).

4. A non-combustible tobacco smoking device based on PTC ceramic heating according to claim 3, wherein: the new energy pushing group (54) comprises a tenth rotating shaft (541), a sixth pushing rod (542), an eleventh rotating shaft (543), fan blades (544), a conveying belt (545), a twelfth rotating shaft (546), a blowing opening (547), a seventh pushing rod (548), an eighth pushing rod (549), a ninth pushing rod (5410), a thirteenth rotating shaft (5411), a tenth pushing rod (5412) and a fourteenth rotating shaft (5413), wherein the tenth rotating shaft (541) is embedded in the sixth pushing rod (542), the tenth rotating shaft (541) is connected with the eleventh rotating shaft (543) through the sixth pushing rod (542), the fan blades (544) are welded on the outer surface of the twelfth rotating shaft (546), the conveying belt (545) is installed on the outer surface of the twelfth rotating shaft (546), the blowing opening (547) is arranged on the lateral side of the twelfth rotating shaft (546), and the seventh pushing rod (548) is hinged with the ninth pushing rod (5410), the ninth push rod (5410) is connected with the tenth push rod (5412) through a thirteenth rotating shaft (5411), the fourteenth rotating shaft (5413) is embedded and installed inside the tenth push rod (5412), the thirteenth rotating shaft (5411) is installed inside the ninth push rod (5410), and the eleventh rotating shaft (543) is embedded and installed inside the eighth push rod (549).