CN109877920B - Numerical control continuous high-frequency assembling machine - Google Patents

Abstract

The invention discloses a numerical control continuous high-frequency assembling machine.A conveying device comprises an assembling machine frame and a feeding frame, wherein the right end of the feeding frame is inserted into the assembling machine frame and extends to the right end of the assembling machine frame, and a conveying belt is assembled on the feeding frame; the pressure device comprises a front pressure device and a side pressure device; the splicing device comprises a positive splicing device and a high-frequency heating device, and the numerical control continuous high-frequency assembling machine is designed, so that when the side pressing pushing heads extrude frame-type timber, the front pressing pushing heads are positioned behind the frame-type timber to extrude the frame-type timber, the distance between a plurality of side pressing gantries is adjusted, the distance between the positive splicing devices is further adjusted, the number of the side pressing gantries is set according to the number of upper beams of the frame-type timber to be spliced, the aim of heating and splicing the frame-type timber with more beams at one time is fulfilled, and the production efficiency is improved.

Description

Numerical control continuous high-frequency assembling machine

Technical Field

The invention relates to the technical field of assembling machines, in particular to a numerical control continuous high-frequency assembling machine.

Background

The splicing of frame type timber on the market mostly adopts the high frequency kludge, the high frequency kludge is high-efficient time-saving, current high frequency kludge is when splicing frame type timber, utilize preceding pressure device and side pressure device to frame type timber extrusion design, utilize high-frequency heating electrode to heat simultaneously, improve the effect of connecting through gluing the fixed between the frame type timber, but it is uncertain to have the crossbeam quantity on the frame type timber, interval between the crossbeam is uncertain, consequently, the heating electrode of current high frequency kludge can only carry out heating concatenation one by one to a plurality of crossbeams, the concatenation efficiency is low, current preceding pressure device and side pressure device autonomous working simultaneously, can not reach linkage complex effect, in order to solve above-mentioned problem, we have proposed a numerical control continuous type high frequency kludge.

Disclosure of Invention

The present invention is directed to a numerical control continuous high frequency assembling machine to solve the above problems.

In order to achieve the purpose, the invention provides the following technical scheme: a numerical control continuous high-frequency assembling machine comprises a conveying device, a pressure device and a splicing device, wherein the conveying device comprises an assembling machine frame and a feeding frame, the upper end of the assembling machine frame is in an open design, the right end of the feeding frame is inserted into the assembling machine frame and extends to the right end of the assembling machine frame, and a conveying belt is assembled on the feeding frame; the pressure device comprises a front pressure device and a side pressure device; the splicing device comprises an anode splicing device and a high-frequency heating device, the high-frequency heating device is assembled in an assembling machine frame, a high-frequency heating anode is integrated on the bottom surface of the anode splicing device, an insulating plate integrated with a high-frequency heating cathode is transversely assembled on the inner wall of the assembling machine frame, the insulating plate is positioned below a conveyor belt, and the high-frequency heating anode and the high-frequency heating cathode are electrically connected with the high-frequency heating device through leads.

Preferably, the front pressure device comprises a front pressure driving device, a front pressure gantry, a front pressure retaining head and a front pressure pushing head, the front pressure driving device comprises a front pressure driving motor fixedly assembled in the middle of the rear edge of the upper surface of the assembling machine frame, the left side and the right side of the lower end of the front pressure driving motor are assembled with a front pressure driving shaft, the outer side end of the front pressure driving shaft is assembled with a differential, the left end and the right end of the upper surface of the assembling machine frame are assembled with the front pressure gantry, a lifting driving device is assembled at the joint of the differential output shaft and the front pressure gantry, the front pressure pushing head is fixedly assembled on the rear sides of the lower surfaces of the two front pressure gantries, and the front pressure retaining head is fixedly assembled on the.

Preferably, the front pressure push head comprises a front pressure push head cylinder support fixedly assembled at the lower end of the front pressure gantry, push head sliding plates are fixedly assembled on the front and back of the inner wall of the front pressure push head cylinder support, an insulating block is assembled between the two push head sliding plates in a sliding manner, a front pressure push head cylinder is fixedly inserted into the upper end of the front pressure push head cylinder support, the telescopic end of the front pressure push head cylinder is fixedly assembled on the insulating block, and a front pressure push head pressing block is fixedly assembled on the lower surface of the insulating block.

Preferably, the side pressure device comprises a side pressure gantry, a side pressure driving device, a side pressure running track, a side pressure running transmission device, a side pressure retaining head and a side pressure pushing head, the side pressure running track is respectively and transversely arranged on the front edge and the rear edge of the upper surface of the frame of the assembling machine, the side pressure driving device is assembled in the side pressure running track in a sliding mode on the rear side, the side pressure driving device is fixedly assembled on the rear side of the side pressure gantry, the front side of the side pressure gantry is assembled in the side pressure running track on the front side in a sliding mode through a connecting piece, transmission gears are assembled on the front surface and the rear surface of the side pressure gantry in a rotating mode, the side pressure driving device comprises a frame and a side pressure driving motor assembled on the frame, the transmission gear on the rear side is assembled on an output shaft of the side pressure driving motor, the side pressure running transmission device comprises vertical plates fixedly assembled on the front edge and, the upper surface of the vertical plate is transversely provided with a tooth groove, the transmission gear is meshed with the tooth groove, the left side surface of the front pressing gantry on the right side is fixedly provided with a side pressing stop head, the right side surface of the side pressing gantry is slidably provided with a side pressing push head, the side pressing push head is fixed with a front pressing push head cylinder support through a connecting block, and the connecting block and the front pressing push head cylinder support are detachably fixed through a bolt.

Preferably, the side pressure push head comprises a side pressure push head cylinder support which is assembled on the side pressure gantry in a sliding mode, a side pressure push head cylinder is fixedly inserted into the upper surface of the side pressure push head cylinder support, a side pressure push head pressing block is fixedly assembled at the lower end of the side pressure push head cylinder, and the rear wall of the side pressure push head pressing block is fixed with the front pressure push head cylinder support through a connecting block.

Preferably, the positive pole splicing device comprises a positive pole and a push head connecting block which are fixedly assembled on a side pressure push head cylinder support, a positive pole cylinder is fixedly assembled on the right side of the upper surface of the positive pole and the push head connecting block, a telescopic end of the positive pole cylinder penetrates through the positive pole and is fixedly assembled with a positive pole pressing block, and a high-frequency heating positive pole is integrated on the bottom surface of the positive pole pressing block.

Preferably, the side wall of the positive pole pressing block is fixedly provided with a positive pole cylinder fixing guide pillar, the positive pole cylinder fixing guide pillar is perpendicular to the bottom surface of the positive pole and the push head connecting block, and the upper end of the positive pole cylinder fixing guide pillar penetrates through the positive pole and the push head connecting block.

Compared with the prior art, the invention has the beneficial effects that: the invention designs a numerical control continuous high-frequency assembling machine which is provided with a front pressing gantry and a side pressing gantry, wherein the front pressing gantry is started to lift by using a front pressing driving motor, the front pressing gantry is driven by the front pressing gantry to synchronously drive a side pressing pushing head, so that the front pressing pushing head can lift up and down, and the front pressing pushing head is positioned behind frame-type timber to extrude the frame-type timber when the side pressing pushing head extrudes the frame-type timber;

the side-pressure pushing head and the front-pressure pushing head are separated by detaching bolts on connecting blocks between the side-pressure pushing head and the front-pressure pushing head, side-pressure gantries slide in a side-pressure running track, the distance between a plurality of side-pressure gantries is adjusted, the side-pressure pushing head and the front-pressure pushing head after displacement is connected through bolts in a fixed mode again, the distance between positive pole splicing devices is further adjusted, the number of the side-pressure gantries is set according to the number of frame type timber upper beams to be spliced, frame type timber with a large number of beams is heated and spliced in one-time mode, and production efficiency is improved.

Drawings

Fig. 1 is a schematic structural diagram of the present patent.

Fig. 2 is a schematic top view of the structure of this patent.

Fig. 3 is a schematic left side view of the structure of this patent.

FIG. 4 is a right sectional view of the structure of the section C-C' in FIG. 1 of this patent.

Fig. 5 is a schematic view of a front pressing pusher structure in this patent.

FIG. 6 is a schematic structural diagram of a side pressure push head and a positive electrode splicing device in the patent.

In the figure: 1 assembling machine frame, 2 feeding frame, 3 conveying belt, 4, front press driving motor, 5 front press driving shaft, 6 differential mechanism, 7 front press gantry, 8 front press stop, 9 front press push head, 91 front press push head cylinder bracket, 92 push head slide plate, 93 front press push head cylinder, 94 insulating block, 95 front press push head press block, 10 side press gantry, 11 side press driving device, 12 side press running track, 13 side press running transmission device, 14 positive pole material splicing device, 141 positive pole and push head connecting block, 142 positive pole cylinder, 143 positive pole press block, 144 positive pole cylinder fixing guide post, 15 side press stop, 16 side press push head, 161 side press push head cylinder bracket, 162 side press push head cylinder and 163 side press push head press block.

Detailed Description

The invention will be further described with reference to specific examples, but the scope of the invention is not limited thereto.

Referring to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5 and fig. 6, the present invention provides a technical solution: a numerical control continuous high-frequency assembling machine comprises a conveying device, a pressure device and a splicing device, wherein the conveying device comprises an assembling machine frame 1 and a feeding frame 2, the upper end of the assembling machine frame 1 is designed to be an opening, the right end of the feeding frame 2 is inserted into the assembling machine frame 1 and extends to the right end of the assembling machine frame 1, and a conveying belt 3 is assembled on the feeding frame 2; the pressure device comprises a front pressure device and a side pressure device; the splicing device comprises a positive splicing device 14 and a high-frequency heating device, the high-frequency heating device is assembled in an assembling machine frame 1, a high-frequency heating positive electrode is integrated on the bottom surface of the positive splicing device 14, an insulating plate of an integrated high-frequency heating negative electrode is transversely assembled on the inner wall of the assembling machine frame 1, the insulating plate is positioned below a conveying belt 3, the high-frequency heating positive electrode and the high-frequency heating negative electrode are electrically connected with the high-frequency heating device through wires, the device is provided with an external PLC, and an electronic device in the PLC controller connecting device controls connection and disconnection of the electronic device.

Feeding unit is used for the transmission to treat the frame-type timber of concatenation, and conveyer belt 3 is tight for chain conveyor and surface, can guarantee not to sink when receiving the extrusion, and pressure device is used for to brush and glues the frame-type timber after assembling and extrudees from top to bottom around, when brush and glue the frame-type timber after assembling by the extruded, utilizes splicing apparatus to brush and glue the frame-type timber after assembling and pressurize and heat, improves the effect through gluing the fixed connection between the frame-type timber.

Preceding pressure device is including pressing drive arrangement before, press longmen 7 before, press fender head 8 and preceding pressure push head 9 before, preceding pressure drive arrangement is including the preceding driving motor 4 that presses of fixed assembly at 1 upper surface rear edge middle part before kludge frame, the preceding pressure driving motor 4 lower extreme left and right sides is equipped with presses drive shaft 5 before pressing, driving motor 4 output shaft passes through gear train drive preceding pressure drive shaft 5 and rotates, the outside end of preceding pressure drive shaft 5 is equipped with differential mechanism 6, press longmen 7 lifting speed to slow down before pressing after the speed governing through differential mechanism 6, convenient control, both ends all are equipped with preceding pressure longmen 7 about kludge frame 1 upper surface, differential mechanism 6 output shaft and preceding pressure longmen 7 junction are equipped with lift drive arrangement, press push head 9 before two fixed being equipped with of the lower surface rear side of longmen 7 before pressing, the fixed being equipped with of the preceding fender head 8 of pressing of kludge frame.

The front pressure driving device is used for driving the front pressure gantry 7 to lift, the front pressure gantry 7 lifts when the driving motor 4 rotates forwards, otherwise the front pressure gantry 7 descends, the lifting part of the front pressure gantry 7 is a sliding block part in a front pressure gantry shell, the sliding block part is assembled in the front pressure gantry shell in a sliding mode, rectangular grooves communicated with each other are formed in the front side wall and the rear side wall of the sliding block part, racks are assembled on the right side wall of the rectangular grooves, an output shaft of a differential mechanism 6 penetrates through the front pressure gantry shell to be inserted into the rectangular grooves, a gear meshed with the racks is fixedly assembled on the outer wall of the output shaft of the differential mechanism 6, the lifting of the racks meshed with the gears is driven through the rotation of the gears, and then the front pressure gantry sliding block part is.

Preceding pressure push head 9 is including fixed assembly in the preceding pressure push head cylinder support 91 that presses longmen 7 lower extreme in the front, and fixed assembly has push head slide 92 around the inner wall of preceding pressure push head cylinder support 91, and it has insulating block 94 to slide between two push head slides 92, and preceding pressure push head cylinder support 91 upper end is fixed to be pegged graft and is pressed push head cylinder 93 in the front, and preceding pressure push head cylinder 93's flexible end is fixed to be assembled on insulating block 94, and insulating block 94 lower fixed surface is equipped with preceding pressure push head briquetting 95.

For preceding pressure behind the air feed of push head cylinder 93, the flexible end of push head cylinder 93 pushes away insulating block 94 and preceding pressure push head briquetting 95 and moves forward, preceding pressure push head 9 is used for pushing forward the frame-type timber after the glue brushing is assembled, press the stop 8 before the frame-type timber contact after the glue brushing is assembled, the frame-type timber after the glue brushing is assembled is extruded in the front and is pressed between stop 8 and the preceding pressure push head 9, avoid the frame-type timber after the glue brushing is assembled to scatter in the conveying process, the gap of junction is too big after avoiding the concatenation.

The lateral pressure device comprises a lateral pressure gantry 10, a lateral pressure driving device 11, a lateral pressure running track 12, a lateral pressure running transmission device 13, a lateral pressure retaining head 15 and a lateral pressure pushing head 16, wherein the lateral pressure running track 12 is respectively and transversely arranged on the front edge and the rear edge of the upper surface of the assembling machine frame 1, the lateral pressure driving device 11 is assembled in the rear lateral pressure running track 12 in a sliding manner, the lateral pressure driving device 11 is fixedly assembled on the rear side of the lateral pressure gantry 10, the front side of the lateral pressure gantry 10 is assembled in the front lateral pressure running track 12 in a sliding manner through a connecting piece, transmission gears are assembled on the front surface and the rear surface of the lateral pressure gantry 10 in a rotating manner, the lateral pressure driving device 11 comprises a frame and a lateral pressure driving motor assembled on the frame, a rear side transmission gear is assembled on an output shaft of the lateral pressure driving motor, the output shaft of the lateral pressure driving motor drives the transmission gears to rotate through a gear set, the lateral pressure running transmission device 13 comprises vertical, the upper surface of a vertical plate is transversely provided with a tooth groove, a transmission gear is meshed with the tooth groove, the left side surface of a front pressure gantry 7 on the right side is fixedly provided with a side pressure stop head 15, the side pressure stop head 15 and the side pressure push head 16 have the same structure, an initial state cylinder is in an extension state, the right side surface of the side pressure gantry 10 is slidably provided with the side pressure push head 16, the side pressure push head 16 can slide on the side pressure gantry 10, in the embodiment, one side pressure faucet 10 is provided with two side pressure push heads 16, the two side pressure push heads 16 are positioned and fixed through bolts after sliding, the position between the two side pressure push heads 16 on the same side pressure gantry 10 is adjusted to be aligned with the frame-type wood edge to be spliced, the side pressure push heads 16 are fixed with a front pressure push head cylinder support 91 through a connecting block, the connecting block and the front pressure push head cylinder support 91 are detachably fixed through bolts, a strip-shaped groove for bolt screwing is transversely arranged on the front, the front and rear parts of the inner wall of the groove are provided with threads.

The side pressure gantry 10 is powered by the side pressure driving device 11 and can slide left and right in the side pressure running track 12, the distance between the adjacent side pressure gantries 10 is convenient to adjust, further the distance between the left and right adjacent anode splicing devices 14 is convenient to adjust, and when the distance is adjusted, bolts on the connecting blocks are firstly dismounted, so that the front pressure push head cylinder support 91 is separated from the side pressure push head 16.

In this embodiment, the three side pressure gantries 10 are assembled in the front side pressure running rails and the rear side pressure running rails 12 in a sliding manner, and are correspondingly suitable for extruding the frame-type timber in a shape like a Chinese character 'ri', if the frame-type timber with more beams needs to be spliced, the frame-type timber with more side pressure gantries can be assembled in the side pressure running rails 12 in a sliding manner, the upper limit is four, and the device is suitable for simultaneously processing the frame-type timber with the same specification and is convenient for batch.

The side pressure push head 16 comprises a side pressure push head cylinder support 161 which is slidably assembled on the side pressure gantry 10, a side pressure push head cylinder 162 is fixedly inserted into the upper surface of the side pressure push head cylinder support 161, a side pressure push head press block 163 is fixedly assembled at the lower end of the side pressure push head cylinder 162, and the rear wall of the side pressure push head press block 163 is fixed with the front pressure push head cylinder support 91 through a connecting block.

After the side pressure push head cylinder 162 supplies air, the telescopic end of the side pressure push head cylinder 162 drives the side pressure push head press block 163 to move downwards, the side pressure push head 16 and the front pressure gantry 7 move synchronously, meanwhile, the front pressure push head 9 is driven to lift, the front pressure push head 9 supplies air independently, and the side pressure push head 16 supplies air and stretches after clamping the frame-type wood assembled by brushing glue.

The side pressure pushing head 16 is used for downwards extruding the edges of the frame-type timber after glue brushing and assembling, so that the frame-type timber after glue brushing and assembling is clamped on the surface of the conveying belt 3, the frame-type timber after glue brushing and assembling is prevented from being scattered in the conveying process, and the gap of the joint after splicing is prevented from being too large.

The anode splicing device 14 comprises an anode and a push head connecting block 141 fixedly assembled on the side pressure push head cylinder support 161, an anode cylinder 142 is fixedly assembled on the right side of the upper surface of the anode and push head connecting block 141, an anode pressing block 143 is fixedly assembled on the telescopic end of the anode cylinder 142 through the anode and push head connecting block 141, and a high-frequency heating anode is integrated on the bottom surface of the anode pressing block 143.

After the air supply of the positive cylinder 142, the telescopic end of the positive cylinder 142 penetrates through the frame-type timber and drives the positive pressing block 143 to extend and clamp the frame-type timber after being assembled by brushing glue extruded by the pressure device, after the high-frequency heating device is communicated, the high-frequency heating positive electrode on the bottom surface of the positive pressing block 143 and the high-frequency heating negative electrode integrated on the insulating plate on the inner wall of the assembling machine frame 1 are matched to generate heat for clamping the frame-type timber after being assembled by brushing glue extruded by the positive pressing block 143, so that the glue is more uniformly distributed after being melted, and the effect of fixing and connecting the frame-type timber through the glue is improved.

The side wall of the positive pole pressing block 143 is fixedly provided with a positive pole cylinder fixing guide post 144, the positive pole cylinder fixing guide post 144 is perpendicular to the bottom surface of the positive pole and push head connecting block 141, the upper end of the positive pole cylinder fixing guide post 144 penetrates through the positive pole and push head connecting block 141, and the positive pole cylinder fixing guide post 144 ensures that the telescopic direction of the positive pole pressing block 143 is kept vertical to avoid inclination.

The working process is as follows:

1. the frame-type timber after being assembled by brushing glue is placed on the front side of the conveying belt 3 and staggered with the position of the front pressing pushing head 9, the specifications of the frame-type timber after being assembled by brushing glue and placed in each processing are unified, the frame-type timber is one of square-shaped, Japanese-shaped and mu-shaped, the position of the side pressure faucet 10 is adjusted according to the beam distance of the frame-type timber, the side pressure faucet 10 is additionally arranged or detached according to different specifications of the frame-type timber processed in each batch, and the quantity of the side pressure faucet 10 is kept consistent with that of the beams of the frame-type timber.

2. When the frame-type timber after glue brushing and assembling is conveyed by the conveying belt 3 and meets the side pressure stop head 15, the conveying belt 3 is controlled to stop running, the front pressure driving device drives the front pressure gantry 7 to descend, the side pressure push head 16 synchronously drives the front pressure gantry 7 to descend, the front pressure gantry 7 and the side pressure push head 16 drive the front pressure push head 9 to descend, when the side pressure push head 16 extrudes the frame-type timber after glue brushing and assembling, the front pressure push head 9 is positioned at the rear side of the frame-type timber after glue brushing and assembling, and the frame-type timber after glue brushing and assembling is extruded between the front pressure stop head 8 and the front pressure push head 9 after being driven by the front pressure push head 9.

3. After the air supply of the positive cylinder 142, the telescopic end of the positive cylinder 142 penetrates through the frame-type timber and drives the positive pressing block 143 to extend and clamp the frame-type timber after being assembled by brushing glue extruded by the pressure device, after the high-frequency heating device is communicated, the high-frequency heating positive electrode on the bottom surface of the positive pressing block 143 and the high-frequency heating negative electrode integrated on the insulating plate on the inner wall of the assembling machine frame 1 are matched to generate heat for clamping the frame-type timber after being assembled by brushing glue extruded by the positive pressing block 143, so that the glue is more uniformly distributed after being melted, and the effect of fixing and connecting the frame-type timber through the glue is improved.

4. After the splicing is completed, the side pressure retaining heads 15 retract, the frame type timber is not shielded, the conveying belt 3 is controlled to be opened to push the finished product out of the processing area, the processing is completed, the new frame type timber after glue brushing and splicing is put on the conveying belt 3 again, the operation is repeated, and the batch processing is performed.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be able to cover the technical scope of the present invention and the equivalent alternatives or modifications according to the technical solution and the inventive concept of the present invention within the technical scope of the present invention.

Claims (4)

1. The utility model provides a numerical control continuous type high frequency kludge which characterized in that: the conveying device comprises an assembling machine frame (1) and a feeding frame (2), the upper end of the assembling machine frame (1) is designed to be an opening, the right end of the feeding frame (2) is inserted into the assembling machine frame (1) and extends to the right end of the assembling machine frame (1), and a conveying belt (3) is assembled on the feeding frame (2); the pressure device comprises a front pressure device and a side pressure device; the splicing device comprises an anode splicing device (14) and a high-frequency heating device, the high-frequency heating device is assembled in an assembling machine frame (1), a high-frequency heating anode is integrated on the bottom surface of the anode splicing device (14), an insulating plate integrated with a high-frequency heating cathode is transversely assembled on the inner wall of the assembling machine frame (1), the insulating plate is positioned below the conveying belt (3), and the high-frequency heating anode and the high-frequency heating cathode are electrically connected with the high-frequency heating device through wires;

the front pressure device comprises a front pressure driving device, front pressure gates (7), front pressure blocking heads (8) and front pressure pushing heads (9), the front pressure driving device comprises a front pressure driving motor (4) fixedly assembled in the middle of the rear edge of the upper surface of an assembling machine frame (1), front pressure driving shafts (5) are assembled on the left and right sides of the lower end of the front pressure driving motor (4), a differential mechanism (6) is assembled at the outer side end of each front pressure driving shaft (5), the front pressure gates (7) are assembled at the left and right ends of the upper surface of the assembling machine frame (1), a lifting driving device is assembled at the joint of an output shaft of the differential mechanism (6) and the front pressure gates (7), the front pressure pushing heads (9) are fixedly assembled on the rear sides of the lower surfaces of the two front pressure gates (7), and the front pressure blocking heads (8) are fixedly assembled on the front edge of the upper surface of the assembling machine;

the front-pressing push head (9) comprises a front-pressing push head cylinder support (91) fixedly assembled at the lower end of the front-pressing gantry (7), push head sliding plates (92) are fixedly assembled on the front and back of the inner wall of the front-pressing push head cylinder support (91), an insulating block (94) is assembled between the two push head sliding plates (92) in a sliding mode, a front-pressing push head cylinder (93) is fixedly inserted into the upper end of the front-pressing push head cylinder support (91), the telescopic end of the front-pressing push head cylinder (93) is fixedly assembled on the insulating block (94), and a front-pressing push head pressing block (95) is fixedly assembled on the lower surface of the insulating block (94);

the lateral pressure device comprises a lateral pressure gantry (10), a lateral pressure driving device (11), a lateral pressure running track (12), a lateral pressure running transmission device (13), a lateral pressure stop head (15) and a lateral pressure push head (16), wherein the lateral pressure running track (12) is respectively and transversely arranged on the front edge and the rear edge of the upper surface of a frame (1) of the assembling machine, the lateral pressure driving device (11) is arranged in the lateral pressure running track (12) on the rear side in a sliding manner, the lateral pressure driving device (11) is fixedly arranged on the rear side of the lateral pressure gantry (10), the front side of the lateral pressure gantry (10) is arranged in the lateral pressure running track (12) on the front side in a sliding manner through a connecting piece, transmission gears are rotatably arranged on the front surface and the rear surface of the lateral pressure gantry (10), the lateral pressure driving device (11) comprises a frame and a lateral pressure driving motor arranged on the frame, the rear side is arranged on an output shaft of the lateral pressure driving motor, the lateral pressure operation transmission device (13) comprises vertical plates fixedly assembled on the front edge and the rear edge of the upper surface of the assembling machine frame (1) respectively, tooth grooves are transversely formed in the upper surfaces of the vertical plates, the transmission gears are meshed with the tooth grooves, a lateral pressure retaining head (15) is fixedly assembled on the right side of the front pressure gantry (7), a lateral pressure pushing head (16) is slidably assembled on the right side of the lateral pressure gantry (10), the lateral pressure pushing head (16) is fixed with a front pressure pushing head cylinder support (91) through a connecting block, and the connecting block is detachably fixed with the front pressure pushing head cylinder support (91) through bolts.

2. The numerical control continuous high-frequency assembling machine according to claim 1, characterized in that: the lateral pressure push head (16) comprises a lateral pressure push head cylinder support (161) which is assembled on the lateral pressure gantry (10) in a sliding mode, a lateral pressure push head cylinder (162) is fixedly inserted into the upper surface of the lateral pressure push head cylinder support (161), a lateral pressure push head pressing block (163) is fixedly assembled at the lower end of the lateral pressure push head cylinder (162), and the rear wall of the lateral pressure push head pressing block (163) is fixed with the front pressure push head cylinder support (91) through a connecting block.

3. The numerical control continuous high-frequency assembling machine according to claim 2, characterized in that: anodal ingredient device (14) are including positive pole and the connecting block (141) of pushing away on side pressure pushing away first cylinder support (161) of fixed mounting, anodal fixed mounting with the upper surface right side of pushing away first connecting block (141) has anodal cylinder (142), the flexible end of anodal cylinder (142) runs through anodal and pushes away first connecting block (141) fixed mounting has anodal briquetting (143), the bottom surface integration of anodal briquetting (143) has the high-frequency heating positive pole.

4. The numerical control continuous high-frequency assembling machine according to claim 3, characterized in that: the side wall of the positive pole pressing block (143) is fixedly provided with a positive pole cylinder fixing guide post (144), the positive pole cylinder fixing guide post (144) is perpendicular to the bottom surface of the positive pole and push head connecting block (141), and the upper end of the positive pole cylinder fixing guide post (144) penetrates through the positive pole and push head connecting block (141).

Images