CN112245275B - Shearing and igniting integrated device - Google Patents

Abstract

The invention provides a shearing and igniting integrated device which comprises an igniting mechanism, a left shearing plate (29), a right shearing plate (39) and a slide block driving mechanism, wherein the left shearing plate (29) and the right shearing plate (39) are oppositely arranged, the left shearing plate (29) is fixedly connected with a left slide block (32), the right shearing plate (39) is fixedly connected with a right slide block (37), the left slide block (32) and the right slide block (37) form relative sliding fit structures with a guide slide rail (31), and the slide block driving mechanism drives the left shearing plate (29) and the right shearing plate (39) to synchronously and reversely slide along the guide slide rail (31). According to the invention, the left shearing plate and the right shearing plate are driven to slide relatively along the guide slide rail through the slide block driving mechanism until the shearing ends on the left shearing plate and the right shearing plate are mutually folded, so that the shearing action is realized, the shearing efficiency and the shearing reliability are effectively improved, and the device has the outstanding advantages of simple structure, space occupation saving and the like.

Description

Shearing and igniting integrated device

Technical Field

The invention relates to the field of structural design of shearing mechanisms, in particular to a shearing and igniting integrated device applied to a moxibustion device.

Background

Moxibustion is to stimulate acupoints or specific parts of human body by using moxa heat generated by moxa sticks after ignition so as to achieve the physiological and biochemical functions of regulating human body disorder, and has the advantages of simple operation, low cost and the like.

However, in the practical application process, if the front end of the moxa stick is not ignited sufficiently, the moxa stick is easy to extinguish halfway, the front end of the extinguished moxa stick is not easy to ignite, and the reliability of the moxa moxibustion is seriously affected; in addition, the moxa sticks which are ignited sufficiently continuously accumulate the burnt moxa ash at the combustion front end in the continuous burning process, and the residual moxa ash not only absorbs heat, but also influences the diffusion of the heat of the moxa fire, so that the reliability of the moxa moxibustion is reduced, and therefore, the burnt moxa ash needs to be cleaned in time.

Disclosure of Invention

The invention aims to solve the technical problems that: aiming at the problems in the prior art, the shearing and igniting integrated device is provided, and the shearing efficiency is improved.

The technical problems to be solved by the invention are realized by adopting the following technical scheme: the utility model provides an integrative device is lighted in shearing, includes ignition mechanism, left shearing board, right shearing board and slider actuating mechanism, left shearing board and right shearing board set up relatively, and left shearing board and left slider fixed connection, right shearing board and right slider fixed connection, left slider, right slider all form relative sliding fit structure with leading the slide rail, slider actuating mechanism drive left shearing board and right shearing board all do synchronous reverse slip along leading the slide rail.

Preferably, the slider driving mechanism comprises a right driven rod, a driving rod and a left driven rod, wherein two opposite ends of the driving rod respectively form a movable hinge structure with one end of the left driven rod and one end of the right driven rod, a movable hinge structure is formed between the other end of the left driven rod and the left slider, and a movable hinge structure is formed between the other end of the right driven rod and the right slider.

Preferably, the left driven rod or the right driven rod is a circular arc structural member.

Preferably, the driving rod is driven by a first motor, and the first motor is fixedly connected with the mounting seat.

Preferably, a heat dissipation net is arranged on the left shearing plate or the right shearing plate.

Preferably, the heat dissipation net is subjected to temperature monitoring through a temperature sensor.

Preferably, the left shear plate or the right shear plate has a semicircular structure.

Preferably, the left slider or the right slider is a T-shaped structural member.

Preferably, the ignition mechanism comprises an electric heating wire which is fixedly arranged on the left shearing plate or the right shearing plate.

Preferably, the heating wires are provided with a plurality of strips, and the plurality of strips of heating wires jointly form an X-shaped structure.

Compared with the prior art, the invention has the beneficial effects that: the left shearing plate and the right shearing plate are oppositely arranged, and form a relative sliding fit structure with the guide slide rail, when the slide block driving mechanism drives the left shearing plate and the right shearing plate to slide relatively along the guide slide rail to be in a folding state, the shearing ends on the left shearing plate and the shearing ends on the right shearing plate are mutually folded to complete shearing action, so that the shearing efficiency and the shearing reliability are effectively improved; in addition, the shearing and igniting integrated device has a simple structure, and can integrate the functions of igniting, shearing and ash removing and the like, thereby being beneficial to reducing the volume of the shearing and igniting integrated device and saving the occupied space of the shearing and igniting integrated device.

Drawings

Fig. 1 is an oblique view (front view) of an automatic moxibustion device.

Fig. 2 is a cross-sectional view taken along A-A in fig. 1.

Fig. 3 is an oblique view (back side) of the automatic moxibustion device.

Fig. 4 is a schematic view of the structure of the molding mechanism.

Fig. 5 is a schematic diagram of the mechanism movement of the forming mechanism.

Fig. 6 is a schematic view of the construction of the propulsion mechanism.

Fig. 7 is an oblique view of the shear mechanism.

Fig. 8 is a front view of the shear mechanism.

Fig. 9 is a side view of the shear mechanism.

Fig. 10 is a schematic of the mechanism movement of the shear mechanism.

Fig. 11 is an oblique view of the support platform mechanism (with the carrier in an expanded state).

Fig. 12 is an oblique view of the support platform mechanism (with the carrier in an upright position).

Fig. 13 is a construction view of the bracket.

Fig. 14 is a partial enlarged view at B in fig. 13.

Fig. 15 is a schematic view of the mechanism movement of the support platform mechanism.

Fig. 16 is a schematic diagram of the working principle of the supporting platform mechanism (the bracket is in a flat state).

Fig. 17 is a sectional view (partially enlarged) taken along the direction C-C in fig. 16.

Fig. 18 is a sectional view (partially enlarged) taken along the direction D-D in fig. 16.

Fig. 19 is a schematic view of the working principle of the supporting platform mechanism (the bracket is in the unfolded state).

Fig. 20 is a sectional view (partially enlarged) taken along the direction E-E in fig. 19.

Fig. 21 is a cross-sectional view (partially enlarged) of fig. 19 taken along the direction F-F.

Fig. 22 is a schematic view of the working principle of the support platform mechanism (the bracket is in an upright state).

Fig. 23 is a sectional view (partially enlarged) taken along the direction G-G in fig. 22.

Fig. 24 is a sectional view (partially enlarged) taken along the direction H-H in fig. 22.

The marks in the figure: the device comprises a base, a 2-transverse sliding rail, a 3-sliding seat, a 4-longitudinal adjusting knob, a 5-supporting table, a 6-bracket, a 7-temperature sensor, a 8-first motor, a 9-throwing port, a 10-pushing sleeve, a 11-driving screw, a 12-protecting cover, a 13-second motor, a 14-third motor, a 15-base, a 16-sliding seat, a 17-fixing bracket, a 18-ash containing box, a 19-forming sleeve, a 20-moxa stick, a 21-pushing rod, a 22-linkage rod, a 23-driving gear, a 24-transverse adjusting knob, a 25-longitudinal sliding rail, a 26-driven gear, a 27-rotating crank, a 28-coupling, a 29-left cutting plate, a 30-heating wire, a 31-guiding sliding rail, a 32-left sliding block, a 33-right driven rod, a 34-driving rod, a 35-left driven rod, a 36-mounting seat, a 37-right sliding block, a 38-cooling net, a 39-right cutting plate, a 51-sliding groove, a 52-containing groove, a 53-vent, a 54-positioning protrusion, a 55-giving groove, a 61-holding groove, a 62-supporting plate, a 64-pin, a 65-pin roll, and a limit supporting plate.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in detail with reference to the accompanying drawings and specific embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

The automatic moxibustion device shown in fig. 1, 2 and 3 mainly comprises a forming mechanism, an ignition mechanism, a shearing mechanism, a propelling mechanism and a supporting platform mechanism, wherein the specific structure of the forming mechanism is shown in fig. 4 and 5, the automatic moxibustion device comprises a forming sleeve 19, a push rod 21 and a linkage rod 22, a fixed connection structure is formed between the forming sleeve 19 and a fixed support 17, the fixed support 17 is fixedly connected with a ash containing box 18, a throwing port 9 and a hollow cavity for containing moxa sticks 20 are respectively formed on the forming sleeve 19, a clearance fit structure is formed between the push rod 21 and the hollow cavity of the forming sleeve 19, one end of the linkage rod 22 is movably hinged with the push rod 21, and the other end of the linkage rod 22 is movably hinged with a rotary crank 27; the rotary crank 27 is fixedly connected with the driven gear 26, a meshing transmission structure is formed between the driven gear 26 and the driving gear 23, and the driving gear 23 is driven by the second motor 13. The ignition mechanism comprises an electric heating wire 30, and the electric heating wire 30 is arranged at the outlet end of the forming sleeve 19.

When the crank 27 is rotated, the push rod 21 can be driven to slide linearly relative to the forming sleeve 19 by the link lever 22, as shown in fig. 5. In order to change the installation position of the second motor 13 conveniently and reduce the occupied space of the forming mechanism, the driving gear 23 and the driven gear 26 are bevel gears; in addition, the gear transmission pair formed by the driving gear 23 and the driven gear 26 is covered by the protective cover 12, so that the movement reliability and the safety of the gear transmission pair are improved.

As shown in fig. 2 and 6, the pushing mechanism mainly includes a pushing sleeve 10 and a driving mechanism thereof, a clearance fit structure is formed between the pushing sleeve 10 and a hollow cavity of the forming sleeve 19, and the pushing sleeve 10 slides linearly relative to the forming sleeve 19 under the action of the driving mechanism thereof.

The driving mechanism of the pushing sleeve 10 comprises a driving screw rod 11 and a sliding seat 16, wherein the driving screw rod 11 is arranged on a base 15, and the base 15 is fixedly connected with a ash containing box 18; the driving screw rod 11 is movably connected with the sliding seat 16 through threads, the sliding seat 16 is fixedly connected with the pushing sleeve 10, and one end of the driving screw rod 11 is connected with an output shaft of the third motor 14 through a coupler 28. When the third motor 14 drives the driving screw 11 to rotate relative to the base 15 through the coupling 28, the sliding seat 16 drives the pushing sleeve 10 to slide linearly synchronously relative to the base 15, so that the pushing sleeve 10 slides linearly relative to the forming sleeve 19.

The shearing mechanism is arranged at the outlet end of the forming sleeve 19, the specific structure of the shearing mechanism is shown in fig. 7, 8, 9 and 10, the shearing mechanism mainly comprises a left shearing plate 29, a right shearing plate 39 and a slide block driving mechanism, the left shearing plate 29 and the right shearing plate 39 are oppositely arranged, the left shearing plate 29 is fixedly connected with a left slide block 32, the right shearing plate 39 is fixedly connected with a right slide block 37, the left slide block 32 and the right slide block 37 form a relative sliding fit structure with a guide slide rail 31, and the slide block driving mechanism drives the left shearing plate 29 and the right shearing plate 39 to synchronously and reversely slide along the guide slide rail 31; the left and right shear plates 29, 39 preferably have a semicircular configuration with the diameter ends thereof being the shear ends. When the left shear plate 29 and the right shear plate 39 synchronously and reversely slide along the guide rail 31 to be in the closed state, the shear ends on the left shear plate 29 and the right shear plate 39 are also closed, so that the shearing action can be completed.

Further, the slider driving mechanism includes a right driven rod 33, a driving rod 34 and a left driven rod 35, wherein two opposite ends of the driving rod 34 form a movable hinge structure with one end of the left driven rod 35 and one end of the right driven rod 33, a movable hinge structure is formed between the other end of the left driven rod 35 and the left slider 32, and a movable hinge structure is formed between the other end of the right driven rod 33 and the right slider 37; the driving rod 34 is driven by the first motor 8, the first motor 8 is fixedly connected with the mounting seat 36, and the mounting seat 36 is fixedly connected with the forming sleeve 19.

When the first motor 8 drives the driving rod 34 to rotate, the driving rod 34 drives the right slider 37 to linearly slide relative to the guide rail 31 through the right driven rod 33, and simultaneously, the driving rod 34 drives the left slider 32 to linearly slide relative to the guide rail 31 through the left driven rod 35, so that the left slider 32 drives the left shearing plate 29, the right slider 37 drives the right shearing plate 39, and the left shearing plate 29 and the right shearing plate 39 synchronously and reversely slide along the guide rail 31, so that the shearing action can be realized by utilizing the mutual matching between the left shearing plate 29 and the right shearing plate 39. In order to improve the flexibility of the action of the shearing mechanism and further improve the shearing efficiency thereof, the left slider 32 and the right slider 37 are preferably T-shaped structural members, and the left driven rod 35 and the right driven rod 33 are preferably circular arc-shaped structural members.

The specific structure of the supporting platform mechanism is as shown in fig. 11, 12 and 18, and mainly comprises a supporting platform 5 and a bracket 6, wherein a containing groove 52 for containing the bracket 6 in a flat state is formed on the supporting platform 5; the bracket 6 comprises two supporting plates 61 which are oppositely arranged, a movable connecting structure which rotates relatively is formed between the two supporting plates 61 through a pin shaft 63, as shown in fig. 13, a sliding shaft 64 is formed at the side part of the supporting plate 61, and a limit clamping groove 65 is formed on the sliding shaft 64, as shown in fig. 14. A chute 51 is formed on the supporting platform 5, and a positioning protrusion 54 is formed at the bottom of the chute 51; the sliding shaft 64 and the sliding groove 51 form a sliding fit structure, and the bracket 6 is in a supporting state relative to the supporting platform 5 through a clamping structure formed between the limiting clamping groove 65 and the positioning protrusion 54, as shown in fig. 15, 20 and 21.

In order to improve the sliding flexibility and smoothness of the sliding shaft 64 relative to the sliding groove 51, an air vent 53 may be formed on the supporting platform 5, the air vent 53 is communicated with the accommodating groove 52, and further, a yielding groove 55 may be formed on the sliding groove 51, where the yielding groove 55 is opposite to the positioning protrusion 54, as shown in fig. 17, 20 and 23.

Generally, as shown in fig. 1 and 3, a longitudinal sliding rail 25 is formed at the bottom of the saddle 5, a sliding fit structure is formed between the longitudinal sliding rail 25 and the sliding seat 3, and a longitudinal adjusting knob 4 is disposed between the longitudinal sliding rail 25 and the sliding seat 3. The sliding seat 3 is arranged on the base 1, the base 1 is provided with a transverse sliding rail 2, a sliding fit structure is formed between the transverse sliding rail 2 and the sliding seat 3, and a transverse adjusting knob 24 is arranged between the transverse sliding rail 2 and the sliding seat 3.

When the longitudinal adjustment knob 4 is released, the pallet 5 can be slid longitudinally with respect to the base 1, said pallet 5 being kept locked in the longitudinal direction with respect to the base 1 when the longitudinal adjustment knob 4 is tightened. When the lateral adjustment knob 24 is released, the pallet 5 can be slid laterally with respect to the base 1, and when the lateral adjustment knob 24 is tightened, the pallet 5 is kept locked in the lateral direction with respect to the base 1. The transverse sliding rail 2 can be provided with a plurality of exhaust holes 53, and the longitudinal sliding rail 25 can also be provided with a plurality of exhaust holes 53; by providing the exhaust hole 53, on the one hand, the weight reduction can be achieved, and on the other hand, the atmospheric pressure can be effectively balanced, thereby improving the sliding smoothness.

When the automatic moxibustion device works,

first, moxa is compacted into moxa sticks by a forming mechanism. Specifically, soft moxa is put into the forming sleeve 19 from the putting port 9, the second motor 13 is started, power is output from the driving gear 23 to the driven gear 26, and the driven gear 26 drives the rotary crank 27 to rotate; in the rotation process of the crank 27, the push rod 21 is driven to slide linearly relative to the forming sleeve 19 by the linkage rod 22, so that moxa in the inner cavity of the forming sleeve 19 can be compacted by the push rod 21 and extruded into a cylindrical moxa roll 20, as shown in fig. 2; after the moxa is compacted, the second motor 13 stops working. Typically, the length of the push rod 21 is equal to the length of the push sleeve 10 to prevent the moxa from entering the pushing mechanism and causing the pushing mechanism to lock.

The formed moxa stick 20 is then ignited by the ignition mechanism. The heating wire 30 in the ignition mechanism is electrified to raise the temperature until the front end of the moxa stick 20 closely attached to the heating wire 30 is ignited. When the moxa stick 20 located in the hollow cavity of the forming sleeve 19 is ignited by the ignition mechanism, moxa ash is continuously accumulated at the combustion part of the moxa stick 20 along with the continuous combustion of the moxa stick, and the moxa ash directly affects the moxibustion effect. For this reason, the moxa ash accumulated in the moxa stick 20 during the burning process may be removed by the shearing mechanism after a certain time.

Specifically, the first motor 8 rotates clockwise, the driving rod 34 drives the left driven rod 35 and the right driven rod 33 to move apart from each other, the left driven rod 35 drives the left slider 32 to slide linearly leftwards along the guide rail 31, the right driven rod 33 drives the right slider 37 to slide linearly rightwards along the guide rail 31, and accordingly the left shear plate 29 and the right shear plate 39 are opened due to the reverse linear motion, as shown in fig. 10. The pushing mechanism pushes the moxa stick 20 forwards along the forming sleeve 19 through the pushing sleeve 10 until the moxa ash accumulated at the front end of the moxa stick 20 is in an opening gap between the left shearing plate 29 and the right shearing plate 39; and then the first motor 8 rotates anticlockwise, the left driven rod 35 drives the left slider 32 to slide right linearly along the guide rail 31, the right driven rod 33 drives the right slider 37 to slide left linearly along the guide rail 31, and when the left shearing plate 29 and the right shearing plate 39 slide reversely along the guide rail 31 synchronously until being in a folding state, the moxa ash accumulated at the front end of the moxa roll 20 can be sheared and removed, and the sheared moxa ash directly falls into the ash containing box 18. After the shearing mechanism removes the moxa ash accumulated by the moxa sticks 20 in the combustion process, the residual moxa sticks 20 in the inner cavity of the forming sleeve 19 are pushed to the ignition mechanism by the pushing mechanism.

It should be noted that: the heating wire 30 on the ignition mechanism can be fixedly arranged on the left shearing plate 29 and the right shearing plate 39, as shown in fig. 7 and 8, so that the shearing mechanism and the ignition mechanism are integrated into a shearing and ignition integrated device, the functions of ignition and ash removal are well integrated, and the volume of the automatic moxibustion device can be reduced.

During the continuous burning of the moxa stick 20, a user may perform moxibustion using the support platform mechanism. The moxa-moxibustion part is firstly placed on the supporting stand 5, and then the supporting height of the bracket 6 is adjusted, as shown in fig. 21 and 24, so that the moxa-moxibustion part is aligned to the combustion end of the moxa stick 20, and moxa-moxibustion can be performed by using moxa heat generated in the combustion process of the moxa stick 20. In the moxibustion process, the longitudinal sliding stroke of the supporting platform 5 relative to the base 1 can be conveniently adjusted through the longitudinal adjusting knob 4, and the transverse sliding stroke of the supporting platform 5 relative to the base 1 can be conveniently adjusted through the transverse adjusting knob 24, so that the moxibustion part can be greatly replaced by a user, the moxibustion temperature can be conveniently controlled by the user through adjusting the distance between the moxibustion part and the combustion end of the moxa stick 20, burn caused by overhigh moxibustion temperature can be prevented, or the moxibustion effect can be reduced by avoiding overlow moxibustion temperature, and the safety and reliability of moxibustion can be ensured. When moxibustion is completed, the user can horizontally spread the bracket 6 to a flat state and put the bracket 6 in the receiving groove 52 on the tray table 5, as shown in fig. 16, 17 and 18.

In order to facilitate the adjustment of the moxibustion position by the user, a plurality of limit clamping grooves 65 on the sliding shaft 64 may be provided, and the plurality of limit clamping grooves 65 are distributed around the sliding shaft 64, and a plurality of positioning protrusions 54 at the bottom of the sliding groove 51 may also be provided, and the plurality of positioning protrusions 54 are distributed in a line shape, as shown in fig. 14, 17, 20 and 23. With such a structural design, the tray 61 may be adjusted in multiple stages by forming different inclination angles with respect to the pallet 5 by using the engagement structure between the positioning projection 54 and the positioning groove 65, as shown in fig. 19, 20, and 21, or the tray 61 may be erected with respect to the pallet 5 by using the engagement structure between the positioning projection 54 and the positioning groove 65, and at this time, the supporting height of the bracket 6 is the highest, as shown in fig. 22, 23, and 24. By adjusting the supporting height of the bracket 6 relative to the supporting stand 5, a user can conveniently and properly adjust the moxibustion part, which is beneficial to improving the safety and reliability of moxibustion.

In order to increase the heating area during moxibustion and improve the moxibustion efficiency and reliability, the left and right shearing plates 29 and 39 may be provided with heat dissipation nets 38, and the heating wires 30 may be provided with a plurality of heating wires 30 to form an X-shaped structure, as shown in fig. 7, 8 and 10.

In the moxibustion process, in order to better ensure the safety of the moxibustion, the top of the supporting plate 61 forms a bracket 62 with an arc structure, as shown in fig. 11, 12 and 13; in addition, the temperature of the heat dissipation net 38 can be monitored by the temperature sensor 7, as shown in fig. 7, 8 and 9, the temperature sensor 7 is electrically connected with a central controller (not shown in the figure), the central controller is also electrically connected with the first motor 8, the second motor 13 and the third motor 14 respectively, and when the temperature sensor 7 detects that the moxibustion temperature at the position of the heat dissipation net 38 is lower than a set value, the central controller starts the third motor 14, and pushes the moxa stick 20 in the inner cavity of the forming sleeve 19 to the ignition mechanism by the pushing mechanism, so that the moxibustion temperature at the position of the heat dissipation net 38 is recovered to a normal level, thereby better ensuring the reliability of moxibustion and improving the automation level of the automatic moxibustion device.

The foregoing description of the preferred embodiment of the invention is not intended to be limiting, but rather to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the invention.

Claims (10)

1. A shear ignition integrated device comprising an ignition mechanism, characterized in that: the device comprises a pushing sleeve (10) and a driving mechanism thereof, wherein the driving mechanism of the pushing sleeve (10) comprises a driving screw rod (11) and a sliding seat (16), the driving screw rod (11) is arranged on a base (15), the base (15) is fixedly connected with a dust containing box (18), the driving screw rod (11) and the sliding seat (16) form threaded movable connection, the sliding seat (16) is fixedly connected with the pushing sleeve (10), one end of the driving screw rod (11) is connected with an output shaft of a third motor (14) through a coupler (28), a clearance fit structure is formed between the pushing sleeve (10) and a hollow cavity of a forming sleeve (19), and when the driving screw rod (11) is driven by the third motor (14) through the coupler (28) to rotate relative to the base (15), the sliding seat (16) drives the pushing sleeve (10) to synchronously slide relative to the base (15) and linearly slide relative to the forming sleeve (19); the left shearing plate (29) and the right shearing plate (39) are oppositely arranged, the left shearing plate (29) is fixedly connected with the left sliding block (32), the right shearing plate (39) is fixedly connected with the right sliding block (37), the left sliding block (32) and the right sliding block (37) form relative sliding fit structures with the guide sliding rail (31), and the sliding block driving mechanism drives the left shearing plate (29) and the right shearing plate (39) to synchronously and reversely slide along the guide sliding rail (31); the left shearing plate (29) and the right shearing plate (39) are arranged at the outlet end of the forming sleeve (19), a throwing opening (9) is formed in the forming sleeve (19), a clearance fit structure is formed between a hollow cavity of the forming sleeve (19) and the push rod (21), the push rod (21) is movably hinged with one end of the linkage rod (22), the other end of the linkage rod (22) is movably hinged with the rotating crank (27), and the rotating crank (27) drives the push rod (21) to linearly slide relative to the forming sleeve (19) through the linkage rod (22) during rotation.

2. The shear-ignition integrated apparatus of claim 1, wherein: the sliding block driving mechanism comprises a right driven rod (33), a driving rod (34) and a left driven rod (35), wherein two opposite ends of the driving rod (34) are respectively in movable hinge connection with one end of the left driven rod (35) and one end of the right driven rod (33), a movable hinge connection structure is formed between the other end of the left driven rod (35) and the left sliding block (32), and a movable hinge connection structure is formed between the other end of the right driven rod (33) and the right sliding block (37).

3. The shear-ignition integrated apparatus of claim 2, wherein: the left driven rod (35) or the right driven rod (33) is a circular arc structural member.

4. The shear-ignition integrated apparatus of claim 2, wherein: the driving rod (34) is driven by the first motor (8), and the first motor (8) is fixedly connected with the mounting seat (36).

5. The shear-ignition integrated apparatus of any one of claims 1-4, wherein: and a heat dissipation net (38) is arranged on the left shearing plate (29) or the right shearing plate (39).

6. The shear-ignition integrated apparatus of claim 5, wherein: the heat dissipation net (38) is used for temperature monitoring through the temperature sensor (7).

7. The shear-ignition integrated apparatus of claim 5, wherein: the left shearing plate (29) or the right shearing plate (39) is of a semicircular structure.

8. The shear-ignition integrated apparatus of any one of claims 1-4, wherein: the left sliding block (32) or the right sliding block (37) is a T-shaped structural member.

9. The shear-ignition integrated apparatus of any one of claims 1-4, wherein: the ignition mechanism comprises an electric heating wire (30), and the electric heating wire (30) is fixedly arranged on the left shearing plate (29) or the right shearing plate (39).

10. The shear-ignition integrated apparatus of claim 9, wherein: the electric heating wires (30) are arranged in a plurality of strips, and the plurality of electric heating wires (30) form an X-shaped structure together.