CN210908369U - Aluminum honeycomb panel fluting cutting all-in-one - Google Patents

Abstract

An aluminum honeycomb panel slotting and cutting all-in-one machine, comprising: the machine comprises a rack, a longitudinal moving frame, a machine head assembly and a plurality of machine body plates, wherein the plurality of machine body plates are longitudinally and horizontally fixed at the upper end of the rack in an extending manner, and the longitudinal moving frame and the machine head are positioned above the machine body plates; the machine head assembly comprises a balance cylinder seat, a machine head plate, a plurality of balance cylinders, a plurality of machine heads and a plurality of corresponding cutter selecting cylinders; the multifunctional slotting machine comprises a plurality of machine heads, a cutter cylinder, a motor shaft, a. It can open out the straight line groove on aluminium honeycomb panel except, can also open out the curve groove on aluminium honeycomb panel, and its fluting efficiency is higher.

Description

Aluminum honeycomb panel fluting cutting all-in-one

Technical Field

The utility model relates to a processing machinery field, concretely relates to aluminum honeycomb panel fluting cutting all-in-one.

Background

In the course of working to aluminum honeycomb panel, often need to open the V-arrangement groove to it, and it is generally installed on moving platform through with the saw bit that current general aluminum honeycomb panel groover is it, and artifical moving platform is slotted to it, and its fluting precision is low, inefficiency, and can't open the curve groove.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to provide an aluminum honeycomb panel fluting cutting all-in-one makes it can push down the processing point of aluminum honeycomb panel when processing aluminum honeycomb panel through head assembly, prevents aluminum honeycomb panel warp in the course of working.

The utility model provides a technical scheme that technical problem adopted is: an aluminum honeycomb panel slotting and cutting all-in-one machine, comprising:

the machine comprises a rack, a longitudinal moving frame, a machine head assembly and a plurality of bed plates, wherein the longitudinal moving frame can be longitudinally movably arranged on the rack in the front-back direction, the machine head assembly can be transversely movably arranged on the longitudinal moving frame, the bed plates are longitudinally and horizontally fixed at the upper end of the rack in an extending manner, and the longitudinal moving frame and the machine head are positioned above the bed plates;

the machine head assembly comprises a balance cylinder seat, a machine head plate, a plurality of balance cylinders, a plurality of machine heads and a plurality of corresponding cutter selecting cylinders; the balance cylinder seat is arranged on the longitudinal moving frame in a transversely sliding manner, and the nose plate is arranged on the balance cylinder seat in a lifting manner; the cylinder body of the balance cylinder is fixedly arranged on the balance cylinder seat, and the piston rod of the balance cylinder is fixedly connected with the nose plate; the cylinder body of the cutter selecting cylinder is fixed on the head plate, and the piston rod of the cutter selecting cylinder is fixedly arranged on the corresponding head;

the multifunctional slotting machine comprises a plurality of machine heads, a cutter cylinder, a motor shaft, a motor.

Preferably, the aluminum honeycomb panel slotting and cutting all-in-one machine further comprises a tail plate fixed at the rear end of the frame, and the front end of the tail plate is opposite to the rear end of the bed body plate.

Preferably, the aluminum honeycomb plate grooving and cutting all-in-one machine further comprises a positioning and pressing device used for transversely positioning and pressing the aluminum honeycomb plate downwards onto the machine body plate, and the positioning and pressing device comprises a plurality of positioning stop blocks and a plurality of cushion blocks; the positioning blocks and the cushion blocks are longitudinally spaced and fixed on the upper end surface of the left support longitudinal beam in a staggered manner; the end faces of the right ends of the cushion blocks are flush to form a positioning surface; the cylinder bodies of the plurality of pressing cylinders are fixed on the frame, and piston rods of the pressing cylinders are upwards penetrated through the cushion blocks and then fixedly connected with a pressing plate;

for each cushion block, two guide pillars penetrate through the cushion block upwards and then are fixed on a pressure plate, one end of the left inner side and the right inner side of the pressure plate is bent downwards to form a pressure edge, the upper end face of the positioning stop block is higher than the upper end face of the cushion block, and the pressure edge and the right end of the cushion block protrude out of the positioning face.

The utility model discloses an aluminum honeycomb panel fluting cutting all-in-one compares among the prior art through the manual fluting of saw bit, and it can also open out the curve groove on aluminum honeycomb panel except can opening out the straight line groove on aluminum honeycomb panel, and its fluting efficiency is higher, can reach 3 ~ 4 m/min.

Drawings

FIG. 1 is an elevation view of an aluminum honeycomb panel grooving and cutting all-in-one machine in accordance with a preferred embodiment of the present invention;

FIG. 2 is a right side view of the aluminum honeycomb panel grooving and cutting all-in-one machine of a preferred embodiment of the present invention;

FIG. 3 is an enlarged schematic view of detail A shown in FIG. 1;

FIG. 4 is a right side view of a portion of the structure of a preferred embodiment of the present invention;

fig. 5 is an elevation view of a longitudinal frame of a preferred embodiment of the present invention;

FIG. 6 is an elevational view of a head assembly in accordance with a preferred embodiment of the present invention;

FIG. 7 is an elevation view of a slotted head in accordance with a preferred embodiment of the present invention;

fig. 8 is an elevation view of a floating press wheel seat and a floating press wheel according to a preferred embodiment of the present invention;

fig. 9 is a schematic view of a portion of a multi-functional router head according to a preferred embodiment of the present invention;

fig. 10 is a pneumatic schematic diagram of a floating device according to a preferred embodiment of the present invention in a certain state;

fig. 11 is a pneumatic schematic diagram of a floating device according to a preferred embodiment of the present invention in another state;

Detailed Description

The technical solution of the present invention will be clearly and completely described with reference to the accompanying drawings. In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The present invention will be further explained with reference to the accompanying drawings.

Please refer to fig. 1 to 5.

The utility model discloses an aluminum honeycomb panel fluting cutting all-in-one, it includes frame (unmarked), longitudinal movement frame 2, head assembly 4 and a plurality of lathe bed board 8. The longitudinal movement frame 2 is provided on the chassis so as to be longitudinally movable in the front-rear direction. The head assembly 4 is transversely movably disposed on the longitudinally movable frame 2. The plurality of bed body plates 8 are fixed at the upper end of the frame in a longitudinally and horizontally extending manner. The longitudinal moving frame 2 and the machine head assembly 4 are positioned above the bed body plate 8. The plurality of bed body plates 8 are transversely arranged side by side, and a blanking gap is reserved between every two bed body plates 8.

Wherein the frame comprises two side frames and a plurality of supporting beams (not shown) which are transversely arranged right and left. Each side frame comprises a support longitudinal beam 1 and a plurality of support legs 1a fixed at the bottom of the support longitudinal beam 1. The plurality of supporting beams are arranged at intervals in the longitudinal direction and transversely connect the two supporting longitudinal beams 1. A plurality of bed panels 8 are fixed to the upper ends of the support beams.

The two transverse ends of the longitudinal moving frame 2 are arranged on the support longitudinal beams 1 on the left and right corresponding sides in a one-to-one correspondence and movable mode. Specifically, a longitudinal linear guide 100 and a longitudinal rack 10 are fixed to one end of the outer side of the support longitudinal beam 1. The upper ends of the two vertically arranged first motor mounting plates 201 are fixed upwards at the near end parts of the left end and the right end of the longitudinal moving frame 2 in a one-to-one correspondence manner. A first slider 204 slidably connected to the left and right longitudinal linear guides 100 is fixed to one end of the left and right inner sides of the first motor mounting plate 201. A gear 203 and a first servo motor 202 are further arranged at one end of the left inner side and the right inner side of the first motor mounting plate 201. The motor shaft of the first servo motor 202 is coaxially fixed with the gear 203, and the axial direction of the gear 203 is arranged along the left-right direction and meshed with the longitudinal rack 10 at the left-right corresponding side.

The head assembly 4 is transversely movably disposed on the longitudinally movable frame 2 at a front side thereof. Specifically, a transverse linear guide 200 is fixed to one end of the front side of the longitudinal moving frame 2, and a transverse rack 20 is fixed to the top of the longitudinal moving frame 2.

The head assembly 4 comprises a transverse slide 40. The transverse slide 40 is provided with a second servomotor (not shown). The motor shaft of the second servomotor is disposed vertically downward and coaxially fixed to a second gear (not shown). The second gear wheel meshes with the transverse rack 20. The transverse slide 40 is arranged on the transverse linear guide 20 in a transversely slidable manner.

In other embodiments, it is preferable that the front end and the rear end of the frame are each provided with a sheet metal shield 103. The head assembly is fixedly covered with a head cover (not marked). A circle of downward transparent PVC soft rubber plate 46 is fixed at the edge of the opening at the lower end of the nose cover. The transparent PVC soft rubber 46 prevents aluminum debris from splashing out of the nose cap when moving with the head assembly.

The utility model discloses an aluminum honeycomb panel fluting cutting all-in-one is still including setting up at the left location closing device 6 of frame. The positioning and pressing device 6 is used for transversely positioning and pressing the aluminum honeycomb plate on the bed plate 8 downwards. The positioning and pressing device 6 includes a plurality of positioning stoppers 61 and a plurality of spacers 62. The positioning stoppers 61 and the spacers 62 are fixed to the upper end surface of the left support side member 1 at intervals in the longitudinal direction and alternately. The right end faces of the plurality of spacers 62 are flush with each other to form a positioning surface.

Corresponding to each cushion block 62, two guide posts penetrate through the cushion block 62 upwards and then are fixed on a pressing plate 63, one end of the left inner side and the right inner side of the pressing plate 63 is bent downwards to form a pressing edge, and the pressing edge is opposite to the cushion block 62 downwards. The upper end surface of the positioning block 61 is higher than the upper end surface of the cushion block 62. The right ends of the press lip and the spacer 62 protrude inwardly beyond the locating surface. The cylinder bodies of a plurality of pressing cylinders (not shown) are fixed on the supporting longitudinal beam 1 on the corresponding side, and the piston rods of the pressing cylinders are upwards penetrated through the cushion block 62 and then fixedly connected with a pressing plate 63.

A tail plate 5 is fixed on the rear end of the frame. The front end of the tail plate 5 is opposite to the rear end of the bed body plate 8. And a cooling water tank 7 is also arranged on the longitudinal moving frame 2 and is connected to the plurality of spray headers through hoses.

In other embodiments, the aluminum honeycomb plate slotting and cutting all-in-one machine of the present invention further comprises two left and right transversely extending press rolls 3. The two compression rollers 3 are respectively positioned at the front side and the rear side of the machine head assembly and are positioned above the bed body plate 8. The left end and the right end of the compression roller 3 are respectively and rotatably arranged on a compression roller seat. The press roller seat is vertically movably arranged on a press roller seat mounting plate. The press roller seat mounting plate is fixedly connected with the left and right corresponding ends of the longitudinal moving frame 2. Can make its roll through adjusting compression roller 3 and push down on aluminium honeycomb panel like this, and then can make the aluminium honeycomb panel in machining area and the laminating of lathe bed board 8.

Specifically, the roller base mounting plate 31 is fixedly connected 8 with the first motor mounting plate 201. Two press roll lifting linear guide rails (not shown) are arranged on the press roll base mounting plate 31. A press roll mounting plate 32 is vertically slidably arranged on each press roll lifting linear guide rail. The lower end of the press roll mounting plate 32 is fixedly connected with a piston rod of a press roll lifting cylinder 33, and a cylinder body of the press roll lifting cylinder 33 is fixed on the press roll base mounting plate 31. The upper end of the roller seat mounting plate 31 is fixedly provided with a roller seat 34. The left and right ends of the press roll 3 are connected to a press roll holder 34 on the left and right sides, respectively, in a one-to-one correspondence by a rolling bearing.

Like this, the compression roller is when putting up longitudinal movement along with longitudinal movement, and compression roller lift cylinder makes the compression roller roll and presses the back on aluminium honeycomb panel, can prevent that aluminium honeycomb panel is adding the warpage deformation in man-hour. Meanwhile, the compression roller lifting linear guide rail can bear rolling friction of the aluminum honeycomb panel to the compression roller, and the compression roller lifting cylinder is prevented from being subjected to longitudinal friction force to reduce the service life of the compression roller lifting cylinder.

Please refer to fig. 6 to 9. The head assembly 4 is arranged on the transverse sliding base 40 in a lifting manner through a screw mechanism. The head assembly 4 further includes a balance cylinder block 41, a head plate 43, a plurality of balance cylinders 42, a plurality of heads, and a cutter selecting cylinder 44 corresponding to the plurality of heads one by one.

The balance cylinder block 41 is fixedly connected with the transverse sliding base 40. The nose plate 43 is arranged on the balance cylinder block 41 in a liftable manner by a lead screw mechanism. For example, a screw motor 45 is fixed on the balance cylinder block 41, a motor shaft thereof is coaxially fixed with a screw (not shown), and a screw nut (not shown) is fixed on the head plate 43, and the screw is vertically arranged and is in threaded connection with the screw nut.

The cylinder body of the balance cylinder 42 is fixed on the balance cylinder seat 41, and the piston rod of the balance cylinder 42 is fixedly connected with the nose plate 43, and is used for helping the lead screw to share weight when the nose plate 43 and the nose are lifted, namely, the weight of the nose plate 43 and the nose is balanced.

Wherein, the cylinder body of the knife selecting cylinder 44 is fixed on the nose plate 43, and the piston rod of the knife selecting cylinder 44 is fixedly connected with the corresponding nose, and is used for making the nose advance downwards to process the aluminum honeycomb panel when one or more noses are selected for operation.

In a preferred embodiment of the present invention, the head assembly includes a cutting head 4a and a multifunctional slotting head 4 c. Wherein, the rotating shafts of the multifunctional slotting machine head 4c and the cutting machine head 4a are both vertically arranged. The cutter head 4a performs an aluminum honeycomb panel cutting operation by a flat bottom milling cutter. The multi-function grooving head 4c performs grooving by a V-shaped milling cutter. Specifically, the multifunctional slotting machine head 4c comprises a multifunctional slotting motor 401c, and the multifunctional slotting motor 401c is fixedly connected with a piston rod of a corresponding knife selecting cylinder. A motor shaft of the multifunctional slotting motor 401c is coaxially fixed with a V-shaped slotting cutter fixing seat 402c, and two slotting cutters 403c are detachably arranged on the slotting cutter fixing seat 402 c. A motor shaft of the multifunctional slotting motor 401c is coaxially fixed with a V-shaped slotting cutter fixing seat 402c, and the slotting cutter fixing seat 402c is detachably provided with a V-shaped slotting cutter 403 c.

Because its axial is vertical to be set up, compare among the prior art through the manual fluting of saw bit, it can open out the straight line groove on aluminium honeycomb panel except, can also open out the curve groove on aluminium honeycomb panel. The slotting efficiency is high and can reach 3-4 m/min.

In another preferred embodiment of the present invention, the head assembly comprises a total of four heads, including a cutting head 4a, a multifunctional grooving head 4c and two grooving heads 4 b.

The slotting machine head 4b comprises a cutter head mounting seat plate 401, the cutter head mounting seat plate 401 is arranged on the machine head plate 43 in a vertically sliding manner, and the cutter head mounting seat plate 401 is fixedly connected with a piston rod of the corresponding cutter selecting cylinder 44. The cutter head mounting seat plate 401 is provided with a cutter head 403, and the cutter head 403 is arranged horizontally in the axial direction. A plurality of grooving bits 405 are fixed to the outer periphery of the cutter head 403 at equal intervals, and the cutting edge of the grooving bit 405 is V-shaped. The cutter head 403 is rotatably provided on a cutter head holder 403b through a bearing 403 a. The cutter head seat 403b is fixedly connected to the cutter head mounting seat plate 401.

The cutter head mounting base plate 401 is also fixedly connected with a motor base plate 402a, and a servo motor 402 is fixed on the motor base plate 402 a. The servo motor 402 is in transmission connection with the cutter head 403 through a belt 402 b.

Wherein, the cutter heads 403 of the two straight slotting machine heads 4b are axially arranged longitudinally and transversely to facilitate slotting longitudinally and transversely respectively.

In other embodiments, the plurality of showerheads are preferably disposed directly below the multifunctional notching head 4c and the cutting head 4a in a one-to-one correspondence. Because the straight slot machine head 4b has fast heat dissipation, the speed of opening the straight slot is higher and can reach 20m/min under the spraying condition.

The utility model discloses an aluminum honeycomb panel fluting cutting all-in-one, it is through setting up two straight flute aircraft noses of opening, wherein open the straight flute aircraft nose and fix on the blade disc that the axial level set up and set up a plurality of V-arrangement tool bits and rotate the fluting, and it is comparatively stable during the fluting, can in time dispel the heat, and the speed of opening the straight flute is very fast.

In other embodiments, it is preferable that each cutter head mounting plate 401 is further provided with a floating pressure wheel device. The floating pressure wheel device comprises an L-shaped fixing plate 404d fixed on the cutter head mounting base plate 401. A slider 404b is vertically slidably disposed on the L-shaped fixing plate 404 d. A vertically arranged adjusting bolt 404e is threaded downwards through a gasket 404c and an L-shaped fixing plate 404d and then is in threaded connection with the sliding block 404 b. A floating pressure roller base 404a is fixed to the lower end of the slider 404 b. A floating pressure roller 404 is rotatably provided on the floating pressure roller base 404a through a bearing. The rotating shaft of the floating pressure wheel 404 is parallel to the rotating shaft of the corresponding cutter disc 403 and is coplanar in a vertical plane. The lower edge of the floating pressure wheel 404 is higher than the lower edge of the revolution contour line of the slotting cutter head 405, and the height difference between the two is the slotting depth.

Preferably, a rubber ring is further fixed on the periphery of the floating pressure wheel 404.

Please refer to fig. 10-11.

The piston rod of the knife selecting cylinder 44 of the utility model is arranged in the knife selecting cylinder 44 through the floating device in a way of floating up and down. The floating device comprises a two-position five-way electromagnetic valve K0, a pressure reducing valve K1, a buffer gas tank K2, a knife selecting cylinder 44 and a compressed gas source K3. Wherein, the buffer gas tank K2 and the compressed gas source K3 are fixedly connected with the knife selecting cylinder 44.

The two-position five-way solenoid valve K0 has an air supply port c1, a first working port c2, a second working port c4, a first exhaust port c3, and a second exhaust port c 5. When the two-position five-way solenoid valve K0 is in the first state (as shown in fig. 9), the first working port c2 is communicated with the air supply port c1, and the second working port c4 is communicated with the second exhaust port c 5; when the two-position five-way solenoid valve K0 is in the second state (as shown in fig. 10), the first working port c2 is communicated with the first exhaust port c3, and the second working port c4 is communicated with the air supply port c 1.

The first working port c2 is communicated with an input end c6 of the pressure reducing valve K1, and an output end c7 of the pressure reducing valve K1 is communicated to an upper end port of the knife selecting cylinder 44 through a buffer air tank K2. The second working port c4 is communicated to the lower port of the blade selecting cylinder 44. The supply port c1 communicates with a compressed air source K3.

When a knife needs to be fed, the two-position five-way electromagnetic valve is electrified, the piston in the electromagnetic valve moves to the right limit position (namely, the first state) under the action of electromagnetic force, compressed gas in a compressed gas source is decompressed by the decompression valve K1 and enters the upper end of the knife selecting cylinder 44 through the buffer gas tank K2, and gas at the lower end of the knife selecting cylinder 44 is discharged through the second gas outlet c 5. At this time, the piston rod of the blade selecting cylinder 44 descends.

When the knife needs to be lifted, the two-position five-way electromagnetic valve is powered off, the piston in the electromagnetic valve moves to the left extreme position (namely, the second state) under the acting force of the spring at the right end, at the moment, compressed gas in the compressed gas source enters the lower end of the knife selecting cylinder 44, and gas at the upper end of the knife selecting cylinder 44 is gathered in the buffer tank K2. At this time, the piston rod of the blade selecting cylinder 44 moves upward until the pressure in the blade selecting cylinder 44 rises to the working pressure.

When the aluminum plate processing device works, when the high and low parts on the aluminum plate to be processed are upwards pressed against the piston rod of the cutter selecting cylinder 44, the buffer tank K2 buffers the piston rod up and down, and the pressure of the aluminum plate on the piston rod is controlled within the working pressure range.

When the surface of the aluminum plate to be processed causes the pressure on the piston rod to be overlarge, the compressed gas in the buffer tank K2 sequentially passes through the pressure reducing valve K1, the first working port c2 and the first exhaust port c3 to release partial pressure.

Among them, the pressure reducing valve may be a pressure reducing valve without a vent function, such as an AR2000 type pressure reducing valve of SMC, or a pressure reducing valve with a vent function, such as an IR1020 type pressure reducing valve of SMC. The difference is that when the pressure reducing valve has no air exhaust function, the upper deviation of the gas pressure floating is slightly larger when the compressed gas of the buffer tank K2 is buffered; when the pressure reducing valve has a gas discharging function, when the compressed gas in the buffer tank K2 is buffered, and the gas pressure exceeds the preset pressure, part of the gas is discharged, so that the lower deviation of the gas pressure floating is slightly larger. Wherein the pressure reducing valve is used to reduce the pressure of a relatively high-pressure gas source, for example 8 kg, to an operating pressure, for example 2 kg.

In another alternative embodiment, the buffer gas tank K2 may be eliminated, and the output end c7 of the pressure reducing valve K1 is directly communicated with the upper port of the knife selecting cylinder 44. At the moment, the pressure reducing valve can only be a pressure reducing valve with an exhaust function, so that the overlarge pressure in the cutter selecting cylinder during working is avoided. After the knife selecting cylinder changes from high to low for multiple times, the pressure reducing valve needs to be repeatedly exhausted for multiple times, so that the knife selecting cylinder needs to be switched to the first state again for gas supplement.

The floating pressure wheel device can be pressed on an aluminum honeycomb panel to be processed by downward abutting of the floating pressure wheel to roll and press when the straight-slot machine head walks to slot, and the pressure of the floating pressure wheel and the upper surface of the aluminum honeycomb panel can be set by a pressure regulating valve arranged on a cutter selecting cylinder, namely, the floating pressure wheel floats downwards under the action of the cutter selecting cylinder, so that the contact pressure of the floating pressure wheel and the aluminum honeycomb panel is constant, and then a linear slot with the consistent depth can be formed on the non-planar aluminum honeycomb panel during slot processing; further, the V-shaped groove can be adjusted through the adjusting bolt to meet the requirements of different groove depths of the V-shaped groove.

In other embodiments, the floating puck device further preferably includes a vertical scale 404g fixed to the L-shaped fixed plate 404d, and an indicator plate 404f fixedly connected to the slider 404b, the indicator plate 404f horizontally abutting the vertical scale 404 g. In this way, the operator can have a certain height reference when adjusting.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of improvements and decorations can be made without departing from the principle of the present invention, and these improvements and decorations should also be regarded as the protection scope of the present invention.

Other parts not described in detail in the present invention belong to the prior art, and are not described herein again.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention.

Claims (3)

1. The utility model provides an aluminum honeycomb panel fluting cutting all-in-one which characterized in that includes:

the machine comprises a rack, a longitudinal moving frame, a machine head assembly and a plurality of bed plates, wherein the longitudinal moving frame can be longitudinally movably arranged on the rack in the front-back direction, the machine head assembly can be transversely movably arranged on the longitudinal moving frame, the bed plates are longitudinally and horizontally fixed at the upper end of the rack in an extending manner, and the longitudinal moving frame and the machine head are positioned above the bed plates;

the machine head assembly comprises a balance cylinder seat, a machine head plate, a plurality of balance cylinders, a plurality of machine heads and a plurality of corresponding cutter selecting cylinders; the balance cylinder seat is arranged on the longitudinal moving frame in a transversely sliding manner, and the nose plate is arranged on the balance cylinder seat in a lifting manner; the cylinder body of the balance cylinder is fixedly arranged on the balance cylinder seat, and the piston rod of the balance cylinder is fixedly connected with the nose plate; the cylinder body of the cutter selecting cylinder is fixed on the head plate, and the piston rod of the cutter selecting cylinder is fixedly arranged on the corresponding head;

the multifunctional slotting machine comprises a plurality of machine heads, a cutter cylinder, a motor shaft, a motor.

2. The aluminum honeycomb panel slotting and cutting all-in-one machine as recited in claim 1, further comprising a tail plate fixed on the rear end of the frame, wherein the front end of the tail plate is opposite to the rear end of the bed body plate.

3. The aluminum honeycomb plate slotting and cutting integrated machine of claim 2 further comprising a positioning and pressing device for transversely positioning and pressing the aluminum honeycomb plate on the machine body plate, wherein the positioning and pressing device comprises a plurality of positioning stoppers and a plurality of cushion blocks; the positioning blocks and the cushion blocks are longitudinally spaced and fixed on the upper end surface of the left support longitudinal beam in a staggered manner; the end faces of the right ends of the cushion blocks are flush to form a positioning surface; the cylinder bodies of the plurality of pressing cylinders are fixed on the frame, and piston rods of the pressing cylinders are upwards penetrated through the cushion blocks and then fixedly connected with a pressing plate;

for each cushion block, two guide pillars penetrate through the cushion block upwards and then are fixed on a pressure plate, one end of the left inner side and the right inner side of the pressure plate is bent downwards to form a pressure edge, the upper end face of the positioning stop block is higher than the upper end face of the cushion block, and the pressure edge and the right end of the cushion block protrude out of the positioning face.

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