CN219425944U - Online laser perforating device of cigarette making machine - Google Patents

Abstract

The utility model discloses an online laser drilling device of a cigarette making machine, which is characterized in that two lasers are fixedly connected in a laser shielding box respectively, wherein a laser emitting end of one laser is sequentially connected with a double-corner power measuring assembly, a small-corner assembly and an adjusting corner assembly B, a laser emitting end of the other laser is sequentially connected with a single-corner power measuring assembly and an adjusting corner assembly A, and the adjusting corner assembly A and the adjusting corner assembly B are correspondingly connected with a laser beam splitting drilling device A and a laser beam splitting drilling device B which are positioned on two opposite sides of a mechanical cigarette rubbing mechanism respectively through respective light path structures. According to the structure, the online laser perforating device of the cigarette machine can ensure the effect of diluting smoke of the cigarette holder and the strength of the cigarette holder.

Description

Online laser perforating device of cigarette making machine

Technical Field

The utility model relates to the technical field of online punching of cigarette filter tips of cigarette making machines, in particular to an online laser punching device of a cigarette making machine.

Background

On-line laser drilling of cigarettes is a new technology developed in the tobacco industry in recent years. The on-line laser drilling of cigarettes is an economic and quick effective means for reducing the tar content of cigarettes. The tipping paper is perforated to form tiny holes by utilizing high-energy laser in the middle of a cigarette filter tip in the cigarette rolling process, and the tipping paper dilutes smoke in the smoking process of the cigarette, so that the tar content is reduced, and the adverse effects on human bodies and the environment are reduced.

At present, a cigarette machine used by a plurality of production enterprises does not have a laser drilling system (such as a ZJ119 cigarette machine) and does not have an online laser drilling function, so that the production enterprises can transfer cigarettes produced by the cigarette machine to an independent laser drilling device for additional drilling, the transfer transportation of the cigarettes is additionally increased in the process, the labor intensity is increased, the production time is prolonged, and the probability of damage to the cigarettes is increased in the transfer process. In addition, if the intensity control of the laser is not good, the laser emitted through holes of the cigarette filter rod can be directly emitted, so that the intensity of the cigarette filter rod is affected, and the qualification rate is reduced; especially, on-line laser drilling is carried out on a cigarette machine, the side wall of the middle part of a cigarette tip of the cigarette needs to be uniformly perforated with tipping paper to form micropores, and how to uniformly punch the micropores through laser without damaging the strength of the cigarette tip is a technical problem which is always required to be solved by a person skilled in the art.

Disclosure of Invention

In order to overcome the defects in the prior art, the utility model provides an online laser perforating device of a cigarette machine, through the structure of the device, when the pulse laser beam irradiates the surface of the middle part of a cigarette tip of a cigarette to perforate, the cigarette rotates under the action of a mechanical cigarette rubbing mechanism, the pulse laser beam is matched with the rotation of the cigarette, and a plurality of rows of micropores with preset quantity are perforated on the surface of the middle part of the cigarette tip of the cigarette along the circumferential direction, so that the effect of diluted smoke of the cigarette tip can be ensured, and meanwhile, the strength of the cigarette tip can also be ensured.

In order to solve the technical problems, the utility model provides the following technical scheme:

the laser perforating device comprises a laser shielding box fixedly connected to one side of a mechanical cigarette rubbing mechanism of the cigarette making machine, two lasers are fixedly connected in the laser shielding box respectively, the laser emitting end of one laser is sequentially connected with a double-corner power measuring assembly, a small-corner assembly and an adjusting corner assembly B, the laser emitting end of the other laser is sequentially connected with a single-corner power measuring assembly and an adjusting corner assembly A, the adjusting corner assembly A and the adjusting corner assembly B are respectively correspondingly connected with a laser beam splitting perforating device A and a laser beam splitting perforating device B which are positioned on two opposite sides of the mechanical cigarette rubbing mechanism through respective optical path structures, and the laser beam splitting perforating device A and the laser beam splitting perforating device B are respectively directed to cigarettes at the corresponding positions of the mechanical cigarette rubbing mechanism.

According to a further improvement scheme, the double-corner dynamometer component is connected with the small-corner component through the light path pipe A, and the small-corner component is connected with the corner adjusting component B through the light path pipe B.

According to a further improvement scheme, the single-corner dynamometer component is connected with the corner adjusting component A through the light path pipe C.

According to a further improved scheme, the optical path structure comprises a single-row component and a double-row component which are sequentially connected, an adjusting corner component A is connected with the single-row component and the double-row component, a corresponding adjusting corner component C is connected with a laser beam splitting and punching device A, an adjusting corner component B is connected with the single-row component and the double-row component, and a corresponding adjusting corner component C is connected with the laser beam splitting and punching device B.

According to a further improved scheme of the utility model, the adjusting corner component A and the adjusting corner component B are respectively connected with corresponding single-double-row components through respective light path pipes D, the single-double-row components are connected with corresponding adjusting corner components C through light path pipes E, and the adjusting corner components C are respectively connected with the laser beam splitting and punching device A or the laser beam splitting and punching device B through corresponding light path pipes F.

According to a further improved scheme, the double-corner dynamometer assembly comprises a base body A, an incident laser channel A, a laser channel B and an outgoing laser channel A are sequentially communicated with each other in the base body A, the laser channel A is perpendicularly connected to the middle of the incident laser channel A, the laser channel B is connected with the tail end of the laser channel A and is perpendicular to the plane where the incident laser channel A and the laser channel A are located, the outgoing laser channel A is connected with the tail end of the laser channel B and is parallel to the laser channel A, the incident laser channel A is perpendicular to the plane where the laser channel A and the outgoing laser channel A are located, a 95% power reflection lens A is arranged at the joint of the incident laser channel A and the laser channel A, a laser power detector A is arranged at the tail end of the incident laser channel A, a total reflection lens A is arranged at the joint of the laser channel A and the laser channel B, and a total reflection lens B is arranged at the joint of the laser channel B and the outgoing laser channel A.

According to a further improved scheme, the single-corner dynamometer assembly comprises a base body B, an incident laser channel B, a laser channel C and an outgoing laser channel B are sequentially communicated with each other in the base body B, the laser channel C is vertically connected to the middle of the incident laser channel B, the outgoing laser channel B is connected with the tail end of the laser channel C and is parallel to the incident laser channel B, a 95% power reflection lens B is arranged at the joint of the incident laser channel B and the laser channel C, a laser power detector B is arranged at the tail end of the incident laser channel B, and a total reflection lens C is arranged at the joint of the laser channel C and the outgoing laser channel B.

According to a further improvement scheme, the small corner assembly comprises a base body C, an incident laser channel C and an emergent laser channel C are sequentially communicated with each other in the base body C, the incident laser channel C is perpendicular to the emergent laser channel C, and a total reflection lens D is arranged at the joint of the incident laser channel C and the emergent laser channel C.

According to a further improved scheme, each adjusting corner assembly comprises a base D, an incident laser channel D and an emitting laser channel D are respectively and sequentially communicated in the base D, the incident laser channel D is perpendicular to the emitting laser channel D, a total reflection lens E is arranged at the joint of the incident laser channel D and the emitting laser channel D, the total reflection lens E is fixedly connected to an adjusting plate, the top angle of the adjusting plate is connected with the base D through an adjusting bolt A, and a spring with pre-compression force is further connected between the adjusting plate and the base D.

According to a further improved scheme, each laser beam splitting and punching device comprises a base body E and a laser emission and punching base which are fixedly connected with each other, an incident laser channel E and a laser corner channel are sequentially arranged in the base body E, an emission beam splitting channel A and an emission beam splitting channel B are respectively arranged in the laser emission and punching base corresponding to the laser corner channel, the incident laser channel E and the laser corner channel are positioned on the same straight line, the emission beam splitting channel A and the emission beam splitting channel B are parallel and perpendicular to the connecting line of the incident laser channel E and the laser corner channel, 50% power reflection lenses are arranged in the laser corner channel at positions corresponding to the beam splitting channel A, a total reflection lens F is arranged in the laser corner channel corresponding to the unsupported support of the beam splitting channel B, a focusing lens A is fixedly arranged in the emission beam splitting channel A, and a focusing lens B is fixedly arranged in the emission beam splitting channel B.

Compared with the prior art, the utility model has the following beneficial effects:

the on-line laser perforating device of the cigarette machine irradiates pulse laser beams to the surface of the middle part of a cigarette tip of a cigarette to perforate, the cigarette rotates under the action of a mechanical cigarette rubbing mechanism, the pulse laser beams are matched with the rotation of the cigarette, and a plurality of rows of micropores with preset number are perforated on the surface of the middle part of the cigarette tip of the cigarette along the circumferential direction, so that the effect of diluting smoke of the cigarette tip can be ensured, and meanwhile, the strength of the cigarette tip can be ensured.

According to the online laser drilling device for the cigarette making machine, different laser directions can be realized for different laser beam splitting and drilling devices through the single-corner power measuring assembly and the cool-corner power measuring assembly, and the laser intensity can be detected, so that the laser intensity is enough to complete drilling and is insufficient to pierce a cigarette holder.

Third, the online laser perforating device of the cigarette making machine can overcome the laser ray trend error caused by the installation error of the laser transmitter and other light path components by adjusting the corner components, thereby ensuring that the laser can be smoothly emitted from the laser beam splitting perforating device of the corresponding light path.

Fourth, the online laser perforating device of the cigarette machine can equally divide the energy of laser into a plurality of beams to be emitted through the action of the laser beam splitting perforating device, so that the laser intensity is reduced, the laser quantity can be increased, the laser perforating efficiency is improved, the number of micropores of the laser is relatively more, and the effect of diluting smoke of a cigarette holder is better.

Drawings

Fig. 1 is a schematic diagram of the structure of the utility model after perspective laser shielding box.

Fig. 2 is an enlarged schematic view of the laser emitting end of the laser of fig. 1.

FIG. 3 is an enlarged schematic cross-sectional view of a dual corner dynamometer assembly.

FIG. 4 is a schematic view of light rays when the dual-corner dynamometer assembly is in operation.

FIG. 5 is an enlarged schematic cross-sectional view of a single-corner dynamometer assembly.

FIG. 6 is a schematic view of light rays when the single-corner dynamometer assembly is in operation.

Fig. 7 is an enlarged schematic cross-sectional view of the small corner assembly.

FIG. 8 is a schematic view of light rays when the small corner assembly is in operation.

FIG. 9 is an enlarged schematic cross-sectional view of the adjustment angle assembly.

FIG. 10 is a schematic view of the light beam when the corner adjustment assembly is in operation.

Fig. 11 is an enlarged schematic sectional view of the laser beam splitting and punching device a and the laser beam splitting and punching device B.

Fig. 12 is a schematic view of light rays when the laser beam splitting and punching device a and the laser beam splitting and punching device B are operated.

Detailed Description

In order that the manner in which the above recited features, objects and advantages of the present utility model are obtained will become readily apparent, a more particular description of the utility model will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings. Based on the examples in the embodiments, those skilled in the art can obtain other examples without making any inventive effort, which fall within the scope of the utility model. The experimental methods in the following examples are conventional methods unless otherwise specified, and materials, reagents, etc. used in the following examples are commercially available unless otherwise specified.

Specific examples:

referring to fig. 1 and fig. 2, the online laser drilling device of the cigarette making machine, and the online laser drilling device of the cigarette making machine are characterized in that: the laser shielding box 1 is fixedly connected to one side of the mechanical cigarette rubbing mechanism of the cigarette making machine, two lasers 2 are fixedly connected to the laser shielding box 1 respectively, the laser emitting end of one laser 2 is sequentially connected with a double-corner power measuring assembly 19, a small-corner assembly 21 and an adjusting corner assembly B13, the laser emitting end of the other laser 2 is sequentially connected with a single-corner power measuring assembly 22 and an adjusting corner assembly A5, the adjusting corner assembly A5 and the adjusting corner assembly B13 are correspondingly connected with a laser beam splitting punching device A3 and a laser beam splitting punching device B8 which are positioned on two opposite sides of the mechanical cigarette rubbing mechanism respectively through respective optical path structures, and the laser beam splitting punching device A3 and the laser beam splitting punching device B8 are respectively pointed to cigarettes on the corresponding positions of the mechanical cigarette rubbing mechanism.

The double-corner dynamometer assembly 19 is connected with the small-corner assembly 21 through the light path pipe A20, and the small-corner assembly 21 is connected with the corner adjusting assembly B13 through the light path pipe B4.

The single-angle dynamometer component 22 is connected with the angle adjusting component A5 through an optical path pipe C6.

The optical path structure comprises a single-row component and a double-row component 9 and an adjustment corner component C11 which are sequentially connected, the adjustment corner component A5 is connected with the single-row component and the double-row component 9, the corresponding adjustment corner component C11 is connected with the laser beam splitting and punching device A3, the adjustment corner component B13 is connected with the single-row and double-row component 9, and the corresponding adjustment corner component C11 is connected with the laser beam splitting and punching device B8.

The adjusting corner component A5 and the adjusting corner component B13 are respectively connected with the corresponding single-double-row component 9 through respective light path pipes D7, the single-double-row component 9 is connected with the corresponding adjusting corner component C11 through light path pipes E10, and the adjusting corner component C11 is respectively connected with the laser beam splitting and punching device A3 or the laser beam splitting and punching device B8 through corresponding light path pipes F12.

As shown in fig. 3, the dual-angle dynamometer assembly 19 includes a base a101, an incident laser channel a, a laser channel B and an outgoing laser channel a are sequentially and respectively connected with the base a101, the laser channel a is perpendicularly connected to the middle of the incident laser channel a, the laser channel B is connected with the end of the laser channel a and is perpendicular to the plane where the incident laser channel a and the laser channel a are located, the outgoing laser channel a is connected with the end of the laser channel B and is parallel to the laser channel a, the incident laser channel a is perpendicular to the plane where the laser channel a and the outgoing laser channel a are located, a 95% power reflection lens a102 is arranged at the joint of the incident laser channel a and the laser channel a, a laser power detector a105 is arranged at the end of the incident laser channel a, a total reflection lens a103 is arranged at the joint of the laser channel a and the laser channel B, and a total reflection lens B104 is arranged at the joint of the laser channel B and the outgoing laser channel a.

As shown in fig. 4, when the dual-angle dynamometer assembly 19 is operated, an incident laser beam is irradiated onto the 95% reflecting mirror a102, and the laser beam is split into two beams. Wherein a laser beam with 5% power is irradiated on the laser power detector a105 for use in laser power real-time detection. After 95% of the laser beams are reflected and turned by the total reflection mirror A103 and the total reflection mirror A104, the laser beams are emitted out of the double-angle dynamometer assembly 19 and enter the next light path component.

As shown in fig. 5, the single-angle dynamometer component 22 includes a base B201, an incident laser channel B, a laser channel C and an outgoing laser channel B are sequentially and respectively connected with the base B201, the laser channel C is vertically connected to the middle of the incident laser channel B, the outgoing laser channel B is connected with the end of the laser channel C and is parallel to the incident laser channel B, a 95% power reflection lens B203 is disposed at the connection between the incident laser channel B and the laser channel C, a laser power detector B204 is disposed at the end of the incident laser channel B, and a total reflection lens C202 is disposed at the connection between the laser channel C and the outgoing laser channel B.

As shown in fig. 6, when the single-angle dynamometer assembly 22 is operated, an incident laser beam is irradiated on the 95% reflecting mirror B203, and the laser beam is split into two beams. Wherein a laser beam with 5% power is irradiated on the laser power detector B204 for use in laser power real-time detection. After 95% of the laser beams are reflected and turned by the total reflection lens C202, the laser beams are emitted out of the single-angle dynamometer component 22 and enter the next light path component.

As shown in fig. 7, the small corner assembly 21 includes a base body C301, an incident laser channel C and an emitting laser channel C are sequentially connected to each other in the base body C301, the incident laser channel C is perpendicular to the emitting laser channel C, and a total reflection lens D302 is disposed at a junction of the incident laser channel C and the emitting laser channel C.

As shown in fig. 8, when the small-angle component 21 is operated, the incident laser beam is irradiated on the total reflection mirror D302, and after the laser beam is reflected and turned, the laser beam exits the small-angle component 21 and enters the next optical path component.

As shown in fig. 9, each corner adjusting component comprises a base D401, an incident laser channel D and an emitting laser channel D are respectively and sequentially communicated in the base D401, the incident laser channel D is perpendicular to the emitting laser channel D, a total reflection lens E402 is arranged at the joint of the incident laser channel D and the emitting laser channel D, the total reflection lens E402 is fixedly connected to an adjusting plate 405, the top corner of the adjusting plate 405 is connected with the base D401 through an adjusting bolt a403, and a spring 404 with pre-pressure is further connected between the adjusting plate 405 and the base D401.

As shown in fig. 10, when the rotation angle adjusting components A5, C11 and B13 are operated, the incident laser beam irradiates the total reflection mirror 402, and after the laser beam is reflected and turned, the laser beam is emitted out of the rotation angle adjusting components A5, C11 and B13 to enter the next light path component. The adjusting bolt A403 is rotated, the total reflection lens E402 can be driven by the adjusting plate 405 to slightly deflect, and the laser beam deviation caused by component errors in the whole light path can be corrected, so that the laser beam can finally and accurately irradiate on the surface of the cigarette.

As shown in fig. 11, the laser beam splitting and punching device A3 and the laser beam splitting and punching device B8 each include a base E501 and a laser emission and punching base 502 that are fixedly connected with each other, an incident laser channel E and a laser corner channel are sequentially disposed in the base E501, an emission and splitting channel a and an emission and splitting channel B are disposed in the laser emission and punching base 502 corresponding to the laser corner channel respectively, the incident laser channel E and the laser corner channel are located in the same straight line, the emission and splitting channel a and the emission and splitting channel B are parallel and perpendicular to a connection line of the incident laser channel E and the laser corner channel, a 50% power reflection lens 503 is disposed in the laser corner channel at a position corresponding to the splitting channel a, a total reflection lens F504 is disposed in the laser corner channel corresponding to the emission and splitting channel B, a focusing lens a505 is fixedly disposed in the emission and splitting channel B506 is fixedly disposed in the emission and splitting channel a.

As shown in fig. 12, when the laser beam splitting and punching device A3 and the laser beam splitting and punching device B8 are operated, an incident laser beam is irradiated on the 50% power reflecting mirror 503, and the laser beam is split into two beams of the same power. The 50% power laser beam passes through the 50% power reflecting mirror 503, is turned by the total reflecting mirror F504, and is focused by the focusing mirror B506 to be emitted out of the laser beam splitting and punching device A3 and the laser beam splitting and punching device B8 to punch small holes on the punched cigarettes; the other 50% power laser beam is reflected and turned by the 50% power reflecting mirror 503, and then is focused by the focusing mirror A505 to be emitted out of the laser beam splitting and punching device A3 and the laser beam splitting and punching device B8 to punch small holes on the punched cigarettes.

In the present utility model, unless expressly stated or limited otherwise, a first feature "above" or "below" a second feature may include both the first and second features being in direct contact, as well as the first and second features not being in direct contact but being in contact with each other through additional features therebetween. Moreover, a first feature being "above," "over" and "on" a second feature includes the first feature being directly above and obliquely above the second feature, or simply indicating that the first feature is higher in level than the second feature. The first feature being "under", "below" and "beneath" the second feature includes the first feature being directly under and obliquely below the second feature, or simply means that the first feature is less level than the second feature.

The foregoing has shown and described the basic principles, principal features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the foregoing embodiments, which have been described in the foregoing description as preferred embodiments of the utility model, but rather that various changes and modifications may be made therein without departing from the spirit and scope of the utility model as defined by the appended claims and their equivalents.

Claims (10)

1. Online laser drilling device of cigarette machine, its characterized in that: the mechanical cigarette rubbing machine comprises a laser shielding box (1) fixedly connected to one side of a mechanical cigarette rubbing mechanism of a cigarette machine, two lasers (2) are fixedly connected in the laser shielding box (1), a laser emitting end of one laser (2) is sequentially connected with a double-rotation angle power measuring assembly (19), a small-rotation angle assembly (21) and an adjusting rotation angle assembly B (13), a laser emitting end of the other laser (2) is sequentially connected with a single-rotation angle power measuring assembly (22) and an adjusting rotation angle assembly A (5), the adjusting rotation angle assembly A (5) and the adjusting rotation angle assembly B (13) are respectively correspondingly connected with a laser beam splitting and punching device A (3) and a laser beam splitting and punching device B (8) which are positioned on two opposite sides of the mechanical cigarette rubbing mechanism through respective optical path structures, and the laser beam splitting and punching device A (3) and the laser beam splitting and punching device B (8) are respectively directed at cigarettes on the corresponding positions of the mechanical cigarette rubbing mechanism.

2. The on-line laser drilling device of the cigarette making machine according to claim 1, wherein: the double-corner dynamometer assembly (19) is connected with the small-corner assembly (21) through the light path pipe A (20), and the small-corner assembly (21) is connected with the corner adjusting assembly B (13) through the light path pipe B (4).

3. The on-line laser drilling device of the cigarette making machine according to claim 1, wherein: the single-corner dynamometer component (22) is connected with the corner adjusting component A (5) through the light path tube C (6).

4. The on-line laser drilling device of the cigarette making machine according to claim 1, wherein: the optical path structure comprises a single-row component (9) and a double-row component (11) which are sequentially connected, the adjustment corner component A (5) is connected with the single-row component and double-row component (9), the corresponding adjustment corner component C (11) is connected with the laser beam splitting and punching device A (3), the adjustment corner component B (13) is connected with the single-row component and double-row component (9), and the corresponding adjustment corner component C (11) is connected with the laser beam splitting and punching device B (8).

5. The on-line laser drilling device of the cigarette making machine according to claim 4, wherein: the laser beam splitting and punching device comprises an adjusting corner component A (5) and an adjusting corner component B (13), wherein the adjusting corner component A (5) and the adjusting corner component B (13) are respectively connected with a corresponding single-double-row component (9) through respective light path pipes D (7), the single-double-row component (9) is connected with a corresponding adjusting corner component C (11) through light path pipes E (10), and the adjusting corner component C (11) is respectively connected with a laser beam splitting and punching device A (3) or a laser beam splitting and punching device B (8) through corresponding light path pipes F (12).

6. The on-line laser drilling device of the cigarette making machine according to claim 1, wherein: the double-corner dynamometer assembly (19) comprises a base body A (101), an incident laser channel A, a laser channel B and an outgoing laser channel A are sequentially communicated with each other in the base body A (101), the laser channel A is perpendicularly connected to the middle of the incident laser channel A, the laser channel B is connected with the tail end of the laser channel A and is perpendicular to the plane where the incident laser channel A and the laser channel A are located, the outgoing laser channel A is connected with the tail end of the laser channel B and is parallel to the laser channel A, the incident laser channel A is perpendicular to the plane where the laser channel A and the outgoing laser channel A are located, a 95% power reflection lens A (102) is arranged at the joint of the incident laser channel A and the laser channel A, a laser power detector A (105) is arranged at the tail end of the incident laser channel A, a total reflection lens A (103) is arranged at the joint of the laser channel A and the laser channel B, and a total reflection lens B (104) is arranged at the joint of the laser channel B and the outgoing laser channel A.

7. The on-line laser drilling device of the cigarette making machine according to claim 1, wherein: the single-corner dynamometer assembly (22) comprises a base body B (201), an incident laser channel B, a laser channel C and an outgoing laser channel B are sequentially communicated with each other in the base body B (201), the laser channel C is perpendicularly connected to the middle of the incident laser channel B, the outgoing laser channel B is connected with the tail end of the laser channel C and is parallel to the incident laser channel B, a 95% power reflection lens B (203) is arranged at the joint of the incident laser channel B and the laser channel C, a laser power detector B (204) is arranged at the tail end of the incident laser channel B, and a total reflection lens C (202) is arranged at the joint of the laser channel C and the outgoing laser channel B.

8. The on-line laser drilling device of the cigarette making machine according to claim 1, wherein: the small corner assembly (21) comprises a base body C (301), an incident laser channel C and an outgoing laser channel C are sequentially communicated with each other in the base body C (301), the incident laser channel C is perpendicular to the outgoing laser channel C, and a total reflection lens D (302) is arranged at the joint of the incident laser channel C and the outgoing laser channel C.

9. The on-line laser drilling device of the cigarette making machine according to claim 1, wherein: each adjustment corner subassembly all includes pedestal D (401), be equipped with incident laser passageway D and ejection laser passageway D respectively in the pedestal D (401) in proper order intercommunication, incident laser passageway D is perpendicular with ejection laser passageway D, the junction of incident laser passageway D and ejection laser passageway D is equipped with total reflection lens E (402), total reflection lens E (402) fixed connection is on adjusting plate (405), the apex angle department of adjusting plate (405) is connected with pedestal D (401) through adjusting bolt A (403), still be connected with between adjusting plate (405) and the pedestal D (401) spring (404) that are equipped with precompression.

10. The on-line laser drilling device of the cigarette making machine according to claim 1, wherein: each laser beam splitting perforating device comprises a base E (501) and a laser emission perforating base (502) which are fixedly connected with each other, an incident laser channel E and a laser corner channel are sequentially arranged in the base E (501), an emission beam splitting channel A and an emission beam splitting channel B are respectively arranged in the laser emission perforating base (502) corresponding to the laser corner channel, the incident laser channel E and the laser corner channel are positioned on the same straight line, the emission beam splitting channel A and the emission beam splitting channel B are parallel and perpendicular to the connecting line of the incident laser channel E and the laser corner channel, a 50% power reflecting lens (503) is arranged in the laser corner channel at the position corresponding to the beam splitting channel A, a total reflecting lens F (504) is arranged in the laser corner channel in an unsupported manner corresponding to the beam splitting channel B, a focusing lens A (505) is fixedly arranged in the emission beam splitting channel A, and a focusing lens B (506) is fixedly arranged in the emission beam splitting channel B.