CN216000736U - Ultrasonic slitting machine - Google Patents

Abstract

The utility model provides an ultrasonic slitting machine which comprises a rack, an objective table, a cutter and a cutter holder, wherein the objective table is arranged on the rack; the objective table is used for bearing materials to be cut, the cutter holder is connected to the rack, the cutter is arranged on the cutter holder, the cutting direction of the cutter is longitudinal, the cutter is adjustable in longitudinal position relative to the objective table, and the cutter is used for cutting the materials arranged on the objective table. Compared with the traditional technology that the object stage is ground after a series of imprints are formed, the service life of the object stage in the ultrasonic slitting machine can be prolonged by several times.

Description

Ultrasonic slitting machine

Technical Field

The utility model relates to the technical field of cutting equipment, in particular to an ultrasonic slitting machine.

Background

The core component of the ultrasonic slitting machine comprises an ultrasonic generator, a cutter and an object stage. The ultrasonic generator generates ultrasonic waves and enables the cutter to vibrate at high frequency, the high-frequency vibration of the cutter generates heat, and the cutting capability of the cutter on materials such as fabrics can be effectively enhanced. The ultrasonic slitting machine is used for cutting materials, has the advantages of automatic edge sealing, no melting change, no burrs and no loose edges of a cutter, ensures that the cut of the materials after cutting is soft, beautiful and flat, and can effectively improve the cutting efficiency. Therefore, the ultrasonic slitting machine is widely applied to the cutting process summary of woven belts, trademark tapes and the like prepared from terylene, chinlon, artificial fabrics, natural rubber and the like.

The object stage is used for carrying materials cut by the belt and abuts against the cutter vibrated by ultrasonic in the actual use process, so that the object stage is also called as an oscillating platform. In the actual use process, the high-frequency vibration cutter not only can effectively cut materials, but also can leave cutting impressions on the objective table. As the number of uses increases, a series of indentations perpendicular to the cutting direction of the tool will eventually be left on the stage. The indentations can be slightly concave, and the cutting efficiency and the cut smoothness of the cutter during cutting are affected. Therefore, when a significant series of indentations has occurred, the stage should be ground flat and then used again. Usually, after grinding for several times, the surface of the object stage is too worn to be used for further grinding, and at the moment, the object stage needs to be replaced. However, the carrier itself is expensive and frequent replacement of the carrier will significantly increase the production costs.

SUMMERY OF THE UTILITY MODEL

Therefore, the ultrasonic slitting machine is required to be provided, the service life of the objective table can be prolonged, and the production cost can be reduced.

According to one embodiment of the utility model, the ultrasonic slitting machine comprises a machine frame, an object stage, a cutter and a cutter holder;

the objective table is used for bearing materials to be cut, the cutter holder is connected to the rack, the cutter is arranged on the cutter holder, the cutting direction of the cutter is longitudinal, the cutter is adjustable in longitudinal position relative to the objective table, and the cutter is used for cutting the materials arranged on the objective table.

In one embodiment, the cutting blade is fixed relative to the blade holder in a longitudinal direction in the horizontal plane, and the blade holder is adjustable relative to the stage in the longitudinal direction in the horizontal plane.

In one embodiment, the device further comprises a connecting piece, the object stage and the connecting piece are both mounted on the frame, the tool apron is connected to the frame through the connecting piece, and the tool apron is adjustable in position relative to the connecting piece in the longitudinal direction in the horizontal plane.

In one embodiment, the cutting tool further comprises a fixing piece and a fixing hole which are matched with each other, a strip-shaped movable through hole which extends along the longitudinal direction is formed in the tool apron, an opening at one end of the movable through hole is located on the surface, close to the cutting knife, of one side of the tool apron, an opening at the other end of the movable through hole is located on the surface, close to the connecting piece, of one side of the tool apron, and the tool apron and the connecting piece are connected with the fixing hole through the fixing piece; the fixing piece passes through the movable through hole and then is detachably connected to the fixing hole, so that the tool apron is connected to the connecting piece.

In one embodiment, the fixing hole is disposed on the connecting member and has an opening facing the movable through hole.

In one embodiment, the tool apron is a long strip extending in the transverse direction, the movable through holes are provided with one or more groups, each group comprises at least two movable through holes arranged at intervals in the longitudinal direction, and the at least two movable through holes are respectively arranged on two sides of the transverse midline of the tool apron.

In one embodiment, a plurality of sets of fixing holes respectively corresponding to the movable through holes are arranged on the connecting piece, each set of fixing holes includes two fixing holes, and the two fixing holes are respectively arranged at two ends of the corresponding movable through holes in an aligned manner.

In one embodiment, the cutting knife has a plurality of cutting knives, and the plurality of cutting knives are arranged on the knife holder in parallel and at intervals.

In one embodiment, the cutting tool further comprises a tool rest, the cutting tool is detachably connected to the tool rest, and the cutting tool is arranged on the tool rest through the tool rest.

In one embodiment, the lateral position of the tool holder relative to the tool holder is adjustable.

Because the cutter in the ultrasonic slitting machine can leave the indentation on the objective table in the ultrasonic vibration in-process to and the cutter interval of ultrasonic slitting machine is adjustable usually in order to cut apart the material of equidimension not, the common messenger of these two factors leaves a long cluster of horizontal cutting indentation on the objective table after the ultrasonic slitting machine is long-time worked. Typically, after the series of cutting impressions is apparent, the stage needs to be lapped flat for continued use. However, the inventors have found that the cutting impressions are formed only in a laterally elongated region of the stage surface, in which a portion of the surface is near the middle, and no impressions are formed in regions on either side of the elongated region.

Based on this finding, the inventors propose a technical idea of extending the service life of the stage. In particular, in the ultrasonic slitting machine of at least one embodiment, the cutting knife is arranged to be capable of moving longitudinally relative to the object stage, so that the service life of the object stage is prolonged. For example, when the cutting device is used for a certain period of time, a part of the surface of the object stage forms a long string of transverse cutting impressions perpendicular to the cutting direction of the cutting knife, and the longitudinal position of the cutting knife can be adjusted to ensure that the cutting knife is pressed on the part without the cutting impressions on the object stage when cutting materials. A stage may be used multiple times and form multiple transverse series of indentations before it is required to grind the stage flat. Compared with the traditional technology that the object stage is ground and reused after a series of indentations are formed, the object stage in the ultrasonic slitting machine in the embodiment can be ground and reused after a plurality of parallel indentations are formed, and therefore the service life of the object stage can be prolonged by multiple times. The degree of lifetime increase depends in particular on the number of stage indentation formations before a single stage grind.

Drawings

FIG. 1 is a schematic structural view of an ultrasonic slitting machine;

FIG. 2 is an elevation view of the tool holder of FIG. 1;

FIG. 3 is a top view of the tool holder of FIG. 1;

FIG. 4 is a cross-sectional view of the AA' region of FIG. 3;

FIG. 5 is a cross-sectional view of the BB' region in FIG. 3;

FIG. 6 is a front view of the connector of FIG. 1;

FIG. 7 is a top view of the connector of FIG. 1;

FIG. 8 is a cross-sectional view of the CC' region of FIG. 7;

FIG. 9 is a cross-sectional view of the DD' region of FIG. 7;

FIG. 10 is a top view of the stage of FIG. 1 illustrating a series of indentations formed therein;

FIG. 11 shows a top view of the stage of FIG. 1 with three series of indentations formed thereon;

wherein each reference numeral and its specific meaning are as follows:

110. a frame; 120. an object stage; 130. a cutter; 140. a tool apron; 141. a movable through hole; 142. a guide groove; 143. a guide mounting hole; 150. a connecting member; 151. a fixing hole; 152. a frame connection hole; 160. a fixing member; 170. a tool holder; 121. a first indentation; 122. a second indentation; 123. and a third indentation.

Detailed Description

In order that the utility model may be more fully understood, reference will now be made to the following description. Preferred embodiments of the present invention are presented herein. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the utility model herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items. As used herein, "plurality" includes two and more than two items. As used herein, "above a certain number" should be understood to mean a certain number and a range greater than a certain number.

The mechanical type divides the strip machine to lean on the cutting edge and wait to cut apart the relative movement of pressure between the material to the realization is to the cutting apart of material, and the ultrasonic wave divides the strip machine to be different with the principle of traditional mechanical type branch strip machine. In the working process of the ultrasonic slitting machine, the temperature of the cutter is increased to cut materials mainly under the action of ultrasonic vibration of the cutter. Ultrasonic vibration can make and produce high frequency collision between cutter and the objective table, therefore the ultrasonic wave divides the strip machine can leave the cutting indentation of a long cluster of perpendicular to cutter cutting direction on the objective table in the use, in order to guarantee the planarization on objective table surface, all need grind the flat processing to the objective table after using for a certain length of time usually. However, the inventors have found that the cutting impressions are formed only in a strip-shaped area of the stage surface, a part of which is near the middle, and no impressions are formed in the areas on both sides of the strip-shaped area.

Based on this finding, the inventors propose a technical idea of extending the service life of the stage. Specifically, according to one embodiment of the utility model, an ultrasonic slitting machine comprises a machine frame, an object stage, a cutter and a cutter holder; the objective table is used for bearing materials to be cut, the cutter holder is connected to the rack, the cutter is arranged on the cutter holder, the cutting direction of the cutter is longitudinal, the cutter is adjustable in longitudinal position relative to the objective table, and the cutter is used for cutting the materials arranged on the objective table.

The "cutting direction" is the direction determined by the cutting line of the blade, and the cutting line has two opposite directions, both of which can be the cutting direction.

In the ultrasonic slitting machine of the embodiment, the cutter is arranged to move longitudinally relative to the object stage so as to prolong the service life of the object stage. For example, when the cutting device is used for a certain period of time, a part of the surface of the object stage forms a long string of transverse cutting impressions perpendicular to the cutting direction of the cutting knife, and the longitudinal position of the cutting knife can be adjusted to ensure that the cutting knife is pressed on the part without the cutting impressions on the object stage when cutting materials. A stage may be used multiple times and form multiple transverse series of indentations before it is required to grind the stage flat. Compared with the traditional technology that the object stage is ground and reused after a series of indentations are formed, the object stage in the ultrasonic slitting machine in the embodiment can be ground and reused after a plurality of parallel indentations are formed, and therefore the service life of the object stage can be prolonged by multiple times. The degree of lifetime increase depends in particular on the number of stage indentation formations before a single stage grind.

It will be appreciated that for an ultrasonic slitter there should be a source of ultrasonic waves for ultrasonically vibrating the cutters.

The cutter can move relative to the rack along the cutting direction of the cutter. For the convenience of understanding, the cutting direction of the cutter is taken as the longitudinal direction, and the direction perpendicular to the cutting direction of the cutter on the horizontal plane is taken as the transverse direction.

In traditional ultrasonic slitting machine, the width of waiting to divide the strip material usually need be adjusted, need realize this moment through the horizontal position of adjusting the cutter, but in order to keep the cutter not to take place the skew when ultrasonic vibration, can fix the cutter position on vertical usually. In order to prolong the service life of the objective table, the ultrasonic slitting machine in the embodiment is specially changed into that the position of the cutting knife relative to the objective table in the longitudinal direction is adjustable.

The specific manner in which the position of the cutting knife relative to the object stage is adjustable may be, for example, to control the cutting knife not to move, so that the object stage moves. However, in the conventional ultrasonic slitting machine, the stage itself has a large mass, and it is inconvenient to move the stage, and the stage is not usually moved in order to ensure stability. Therefore, the position of the cutting knife relative to the object stage can be adjusted in a specific way, for example, the knife holder is controlled to be kept immovable in the longitudinal direction relative to the machine frame, so that the cutting knife can move in the longitudinal direction relative to the knife holder; in another example, the cutting blade is controlled to be longitudinally immovable relative to the blade holder, so that the blade holder, at least part of which is provided with the cutting blade, can be longitudinally moved relative to the machine frame. It will be appreciated that in actual design consideration should preferably be given to controlling the movement of the cutting or seating blade.

Optionally, in one particular example, the cutting blade is fixed relative to the blade holder in a longitudinal direction in the horizontal plane, and the blade holder is adjustable relative to the stage in the longitudinal direction in the horizontal plane. Because the cutter can produce ultrasonic vibration at the course of the work, consequently with the cutter design for the blade holder on the cutting direction of cutter is static, can reduce the stress that the connection position between cutter and the blade holder received, avoid as far as possible setting up the cutter to the extra damage that can bring the machine relatively frame longitudinal movement.

Further, in some conventional ultrasonic slitting machines, the tool apron can also move transversely relative to the machine frame in a direction perpendicular to the cutting direction of the cutter as required, and then a connecting piece can be further arranged to avoid damage caused by relative movement between the tool apron and the machine frame. The objective table and the connecting piece are both arranged on the rack, the tool apron is connected to the rack through the connecting piece, and the tool apron is adjustable in position in the longitudinal direction in the horizontal plane relative to the connecting piece.

Specifically, in order to further understand the ultrasonic slitting machine in the above embodiments, referring to fig. 1, an embodiment of the ultrasonic slitting machine includes a frame 110, an object stage 120, a cutter 130, and a cutter seat 140. The objective table 120 is disposed at the bottom to support the cloth to be cut. The cutter 130 is disposed right above the stage 120, and is pressed against the stage 120 to cut the cloth disposed on the stage 120. The tool post 140 is used for installing the cutting tool 130, and the tool post 140 is fixedly connected to the frame 110.

In the ultrasonic slitting machine, the cutter holder 140 includes a connecting member 150 and the cutter holder 140, the cutter 130 is disposed on the cutter holder 140, and the connecting member 150 is disposed between the frame 110 and the cutter holder 140 and connected to the cutter holder 140 and the frame 110. The position of the connecting member 150 relative to the frame 110 in the cutting direction is fixed, and the position of the tool holder 140 relative to the connecting member 150 in the longitudinal direction is adjustable.

The "longitudinal direction" and the "transverse direction" are two mutually perpendicular directions on a horizontal plane. Specifically, please refer to the three-dimensional coordinate system identified in fig. 1, wherein the x direction is perpendicular to the paper surface, the y direction and the z direction are located on the paper surface, the x direction perpendicular to the paper surface is a longitudinal direction, the y direction located on the paper surface is a transverse direction, and the longitudinal direction and the transverse direction refer not only to the longitudinal direction and the transverse direction on the horizontal plane where the cutting position of the cutter is located, but also to the longitudinal direction and the transverse direction on other horizontal planes.

The position of the tool holder 140 relative to the connecting member 150 in the longitudinal direction can be adjusted in various ways. The embodiment of the present invention is described by taking one of the examples. Referring to fig. 2 to 5, fig. 2 shows a front view of the insert seat 140, fig. 3 shows a top view of the insert seat 140, fig. 4 shows a cross-sectional view of an AA 'surface of the insert seat 140, and fig. 5 shows a cross-sectional view of a BB' surface of the insert seat 140. The region with parallel oblique lines in fig. 2 shows an internal cross-sectional view taken along the region.

Referring to fig. 2 and 3, in a specific example, the tool holder 140 is provided with a movable through hole 141 extending along the cutting direction, and the tool holder 140 is movably connected to the connecting member 150 through the movable through hole 141. One end of the movable through hole 141 is opened on a side surface of the tool holder 140 close to the cutter 130, and the other end is opened on a side surface of the tool holder 140 close to the connecting member 150. Through the mode of opening movable through-hole 141 on blade holder 140, realize that the relative position between blade holder 140 and connecting piece 150 is adjustable, reduce the transformation to original equipment itself as far as possible.

To facilitate understanding of the specific connection between the tool holder 140 and the connecting member 150, please refer to fig. 6 to 9, in which fig. 6 shows a partial front view of the connecting member 150, fig. 7 shows a partial top view of the connecting member 150, fig. 8 shows a cross-sectional view of the AA 'surface of the connecting member 150, and fig. 9 shows a cross-sectional view of the BB' surface of the connecting member 150.

In consideration of the ultrasonic vibration of the cutter 130 during actual use, it is necessary to maintain the fixation between the tool holder 140 and the connecting member 150 during use.

In one specific example, the ultrasonic slitter further comprises a fixing hole 151 and a fixing member 160, and the fixing member 160 and the fixing hole 151 are used together to fix the tool post 140 to the connecting member 150. In the actual assembly process, the fixing member 160 first extends into the movable through hole 141 of the tool holder 140, and then enters the fixing hole 151 of the connecting member 150 to complete the fixing. When the position of the tool apron 140 needs to be adjusted, the fixing member 160 and the fixing hole 151 may be detached first, the tool apron 140 is adjusted in position by means of the movable through hole 141, and finally the fixing member 160 is inserted into the fixing hole 151, and the tool apron 140 is fixed on the connecting member 150 again.

Fig. 6 to 7 show a specific example of providing the fixing hole 151, wherein the fixing hole 151 is opened on the connecting member 150, the fixing hole 151 is opened opposite to the movable through hole 141, and the fixing member 160 is detachably connected to the fixing hole 151 after passing through the movable through hole 141. In practice, the fixing member 160 is easily moved to separate the tool holder 140 from the connecting member 150. In another specific example, the fixing member 160 may be disposed on the connecting member 150, the fixing hole 151 may be separately disposed on another component, and the fixing member 160 may extend into the fixing hole 151 of the component after extending into the movable through hole 141 to connect the tool holder 140 and the connecting member 150. Alternatively, the fixing hole 151 is a screw hole having a screw thread on an inner wall, and the fixing member 160 is a screw adapted to the screw hole. When the fixing member 160 is provided on the connection member 150, the fixing hole 151 may be separately provided on the additional nut.

In addition, in one specific example, the connecting member 150 further has a frame connecting hole 152, and correspondingly, the frame 110 has a projection corresponding to the frame connecting hole 152, and the connecting member 150 is connected to the frame 110 through the frame connecting hole 152 and the projection.

In one specific example, the tool holder 140 is an elongated shape extending in the transverse direction, and the movable through holes 141 have one or more groups, each group includes two movable through holes 141 arranged at intervals in the longitudinal direction, and the two movable through holes 141 are respectively disposed on two sides of the transverse midline of the tool holder 140. For example, as shown in fig. 3, there are four sets of two movable through holes 141, and two movable through holes 141 are spaced apart from each other in the longitudinal direction. The two movable through holes 141 which are longitudinally arranged at intervals are arranged, so that the longitudinal movement range of the tool apron 140 can be widened as much as possible on the premise of keeping the integrity of the long tool apron 140.

Further, corresponding to the arrangement of the movable through holes 141, the connecting member 150 is also provided with a plurality of sets of fixing holes 151 respectively corresponding to the movable through holes 141, and each set of fixing holes 151 corresponds to one movable through hole 141. Each group of fixing holes 151 includes two fixing holes 151, and the two fixing holes 151 are respectively aligned at two ends of the corresponding movable through hole 141. The movable through hole 141 is provided as described above to improve the connection stability between the connecting member 150 and the holder 140 mainly in the case of widening the longitudinal movement range of the holder 140. For example, when the fixing member 160 moves from one end of one of the movable through holes 141 to the other end, two fixing members 160 can still participate in the fixed connection between the connecting member 150 and the tool holder 140 in one set of the movable through holes 141, so that the stable connection between the connecting member 150 and the tool holder 140 can be maintained. If only one fixing member 160 is connected between the connecting member 150 and the tool holder 140 in one set of the movable through holes 141, the connecting portion between the connecting member 150 and the tool holder 140 is subjected to an excessive stress, and thus the connecting portion is easily loosened.

Further, the two movable through holes 141 of the set of movable through holes 141 may be configured to have the same shape, so that the longitudinal movement range of the tool holder 140 can be further increased while the two fixing members 160 are connected to the set of movable through holes 141.

In one specific example, the cutting tool further comprises a tool rest 170, the cutting tool 130 is detachably connected to the tool rest 170, and the tool rest 170 is connected to the tool holder 140. The tool holder 170 may serve as a transition piece 150 between the cutting blade 130 and the tool holder 140 to facilitate removal and replacement of the cutting blade 130.

Further, the lateral position of tool holder 170 relative to tool holder 140 is adjustable. In particular, the tool holder 140 further has a guide on a face thereof on which the tool holder 170 is provided, the tool holder 170 being disposed on the guide, the tool holder 170 being movable in a lateral direction on the guide. Optionally, tool holder 170 is disposed on a transverse midline of tool holder 140.

Further, a guide groove 142 is formed on a side of the holder 140 adjacent to the holder 170, and a guide member may be disposed in the guide groove 142, which is located on a lateral centerline of the holder 140. At this time, two movable through holes 141 of the set of movable through holes 141 may be disposed at both sides of the guide groove 142.

In addition, the tool holder 140 further has a plurality of guide mounting holes 143, the guide mounting holes 143 may be provided, and the guide is also provided with a protrusion adapted to each guide mounting hole 143, and the guide is fixedly connected to the tool holder 140 through the guide mounting holes 143 and the protrusions.

In one specific example, there are a plurality of cutting knives 130, a plurality of cutting knives 130 are arranged in parallel, and two adjacent cutting knives 130 are arranged at intervals.

Fig. 10 shows a top view of the stage 120 after a prolonged use forming a series of transverse first indentations 121. The cutting blade 130 is not longitudinally movable relative to the stage 120 as in the conventional technique, and therefore only forms a series of transverse indentations. After the stage 120 of the ultrasonic slitter in the above embodiment forms a series of indentations, one or more series of transverse indentations may be formed in addition to the existing first indentation 121 by adjusting the position of the cutter 130 relative to the stage 120 in the longitudinal direction. For example, in fig. 11, in the ultrasonic slitting machine according to the above embodiment, a second indentation 122 and a third indentation 123 can be formed on the stage 120. If the stage 120 is declared obsolete after 5 passes through the smoothing, only 6 series of indentations can be made on the stage 120. However, if the ultrasonic slitting machine of the above embodiment is used, 3 series of indentations can be formed before each smoothing, 18 series of indentations can be generated on the stage 120, and the effective service life can be prolonged by 3 times. It will be appreciated that the above data is provided as an example to aid understanding, and that in practice the specific values will vary for different sizes and models of stage 120.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the utility model. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. An ultrasonic slitting machine is characterized by comprising a rack, an objective table, a cutter and a cutter holder;

the objective table is used for bearing materials to be cut, the cutter holder is connected to the rack, the cutter is arranged on the cutter holder, the cutting direction of the cutter is longitudinal, the cutter is adjustable in longitudinal position relative to the objective table, and the cutter is used for cutting the materials arranged on the objective table.

2. An ultrasonic slitter according to claim 1, wherein the cutter is fixed relative to the cutter holder in a longitudinal direction in the horizontal plane, the cutter holder being adjustable in position relative to the stage in the longitudinal direction in the horizontal plane.

3. The ultrasonic slitter according to claim 2, further comprising a connector, wherein the stage and the connector are both mounted on the frame, the blade holder is connected to the frame by the connector, and the blade holder is adjustable in position relative to the connector in a longitudinal direction in a horizontal plane.

4. The ultrasonic slitting machine as claimed in claim 3, further comprising a fixing member and a fixing hole, wherein the fixing member and the fixing hole are adapted to each other, the blade holder is provided with a strip-shaped movable through hole extending in a longitudinal direction, one end of the movable through hole is open at a side surface of the blade holder close to the cutter, the other end of the movable through hole is open at a side surface of the blade holder close to the connecting member, and the blade holder and the connecting member are connected with the fixing hole through the fixing member; the fixing piece passes through the movable through hole and then is detachably connected to the fixing hole, so that the tool apron is connected to the connecting piece.

5. The ultrasonic slitter according to claim 4, wherein the fixing hole is provided on the connecting piece and the fixing hole has an opening facing the movable through hole.

6. The ultrasonic slitter according to claim 5, wherein the tool apron is elongated in a transverse direction, the plurality of sets of the movable through holes are arranged in a longitudinally spaced manner, and the at least two movable through holes are respectively disposed on two sides of a transverse center line of the tool apron.

7. The ultrasonic strip splitter according to claim 6, wherein a plurality of sets of fixing holes are formed in the connecting member and respectively correspond to the movable through holes, each set of fixing holes comprises two fixing holes, and the two fixing holes are respectively aligned and arranged at two ends of the corresponding movable through holes.

8. The ultrasonic slitter according to any one of claims 1 to 7, wherein the plurality of cutters are arranged on the tool apron in parallel and at intervals.

9. The ultrasonic strip separator according to any one of claims 1-7, further comprising a cutter holder, wherein the cutter is detachably connected to the cutter holder, and the cutter is arranged on the cutter holder through the cutter holder.

10. An ultrasonic slitter according to claim 9, wherein a lateral position of the blade holder relative to the blade seat is adjustable.

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