CN111645168B - Automatic change 5G basic station ceramic filter production system - Google Patents

Abstract

The invention relates to the field of filter production, in particular to an automatic 5G base station ceramic filter production system which comprises a mixing drum, a door-shaped frame, a baffle, a sliding plate, a partition plate, a sliding hole, a sliding cylinder, an electric push rod I and an L-shaped frame. The rear side fixedly connected with L of churn appears the frame, the articulated downside of connecting at the smooth flitch in upper end of L shape frame, both ends and the equal fixedly connected with division board in middle part about smooth flitch upside, three division board divide into two regions with smooth flitch, the upside fixedly connected with separation blade of churn, two separation blades of fixedly connected with on the separation blade, the front portion in two regions on the smooth flitch is inserted respectively to the lower part of two separation blades, fixedly connected with electric putter I on the L shape frame, electric putter I's expansion end fixedly connected with slide cylinder, the right side of smooth flitch is provided with the slide opening, slide cylinder sliding connection is on the slide opening.

Description

Automatic change 5G basic station ceramic filter production system

Technical Field

The invention relates to the field of filter production, in particular to an automatic 5G base station ceramic filter production system.

Background

The invention discloses a bending device for producing a filter, which relates to the field of filter production, and particularly relates to a bending device for producing a filter, which comprises a base, wherein a movable plate is arranged on the upper side of the base, a damping mechanism is arranged between the movable plate and the base, a sliding chute is arranged at the top end of the movable plate, a feeding mechanism is arranged on the sliding chute in a sliding connection manner, a bending mechanism fixedly connected with the movable plate is arranged on the left side of the feeding mechanism, and a reinforcing mechanism is arranged between the bending mechanism and the feeding mechanism. Can drive both sides splint through the stay cord and remove to the material direction to provide further fixed to the material, effectively guaranteed product quality. However, the ceramic filter cannot be manufactured by mixing ceramic raw materials.

Disclosure of Invention

The invention provides an automatic 5G base station ceramic filter production system, which has the beneficial effect that the ceramic filter can be prepared by mixing ceramic raw materials.

The invention relates to the field of filter production, in particular to an automatic 5G base station ceramic filter production system which comprises a mixing drum, a door-shaped frame, a baffle, a sliding plate, a partition plate, a sliding hole, a sliding cylinder, an electric push rod I and an L-shaped frame.

The rear side fixedly connected with L of churn appears the frame, the articulated downside of connecting at the smooth flitch in upper end of L shape frame, both ends and the equal fixedly connected with division board in middle part about smooth flitch upside, three division board divide into two regions with smooth flitch, the upside fixedly connected with separation blade of churn, two separation blades of fixedly connected with on the separation blade, the front portion in two regions on the smooth flitch is inserted respectively to the lower part of two separation blades, fixedly connected with electric putter I on the L shape frame, electric putter I's expansion end fixedly connected with slide cylinder, the right side of smooth flitch is provided with the slide opening, slide cylinder sliding connection is on the slide opening.

Automatic change 5G basic station ceramic filter production system still includes motor I, horizontal slat and puddler, the upside fixedly connected with horizontal slat of churn, the upside middle part fixedly connected with motor I of horizontal slat, in motor I's the output shaft inserted the churn, a plurality of puddlers of fixedly connected with on motor I's the output shaft.

Automatic change 5G basic station ceramic filter production system still includes hinge post, lower side door and keeps off along, the right side lower part fixedly connected with hinge post of churn, and the lower extreme of hinge post is articulated to be connected with down the side door, and the lower side door closure is at the lower part opening part of churn, and the equal fixedly connected with in both ends keeps off along around the lower side door upside.

The automatic 5G base station ceramic filter production system further comprises a bottom plate, an electric push rod II and a rear support, the rear support is fixedly connected to the bottom plate, the mixing drum is fixedly connected to the upper end of the rear support, the electric push rod II is fixedly connected to the upper side of the bottom plate, and the movable end of the electric push rod II is supported on the lower side of the lower side door.

The automatic 5G base station ceramic filter production system further comprises a semi-cylindrical box, a fixing shaft, a shaft bracket, heating wires, a lifting plate and a motor III, wherein the shaft bracket is fixedly connected to the upper side of the bottom plate, the upper portion of the shaft bracket is rotatably connected with the fixing shaft, the semi-cylindrical box is fixedly connected to the right end of the fixing shaft, the motor III is fixedly connected to the right side of the semi-cylindrical box, an output shaft of the motor III is inserted into the semi-cylindrical box, the lifting plate is fixedly connected to an output shaft of the motor III, a plurality of heating wires are arranged on the outer side of the semi-cylindrical box, and the semi-cylindrical box is.

Automatic change 5G basic station ceramic filter production system still includes stand, spring loop bar, left side pole and long jack, the right-hand member fixedly connected with left side pole of fixed axle, be provided with long jack on the left side pole, the equal fixedly connected with stand in both ends around the spring loop bar, the equal fixed connection of lower extreme of two stands is on the bottom plate, the spring loop bar passes long jack, compression spring has all been cup jointed to two parts around the spring loop bar, two compression springs are located both sides around the left side pole respectively.

The automatic 5G base station ceramic filter production system further comprises a poke rod, a motor II, a translation frame, a trapezoidal slide rail and a fastening screw, the left part of the bottom plate is provided with the trapezoidal slide rail arranged in the front-back direction, the lower part of the translation frame is connected onto the trapezoidal slide rail in a sliding mode, the lower part of the translation frame is connected with the fastening screw through threads, the fastening screw is tightly propped on the trapezoidal slide rail, the upper part of the translation frame is fixedly connected with the motor II, the output shaft of the motor II is fixedly connected with the poke rod, and the poke rod is located in front of the semi-cylindrical box.

Automatic change 5G basic station ceramic filter production system still includes the rectangle seat, the silo, the briquetting, the lift post, electric putter III, the flatting revolving beam, motor IV and metallic channel, rectangle seat fixed connection is in the front portion of bottom plate, be provided with the silo on the rectangle seat, the front portion of silo is provided with the three metallic channel that is parallel to each other, the right-hand member fixedly connected with motor IV of rectangle seat, fixedly connected with flatting revolving beam on motor IV's the output shaft, the vertical sliding connection in left end of flatting revolving beam has the lift post, the lower extreme fixedly connected with briquetting of lift post, fixedly connected with electric putter III on the flatting revolving beam, electric putter III's expansion end fixed connection is on the upper portion of lift post.

The automatic 5G base station ceramic filter production system further comprises a cutter and a motor V, the front side of the rectangular seat is fixedly connected with the motor V, the output shaft of the motor V is fixedly connected with the cutter, and the cutter is attached to the front end face of the rectangular seat.

The automatic 5G base station ceramic filter production system has the beneficial effects that:

the invention relates to an automatic 5G base station ceramic filter production system which can be used for mixing ceramic raw materials to prepare a ceramic filter. Different ceramic powder materials are respectively placed in two areas on a sliding plate according to the required proportion, the ceramic powder materials placed in the two areas are convenient to observe the using amount, two blocking pieces are respectively blocked at the front parts of the two areas, at the moment, the ceramic powder materials in the two areas cannot fall into a stirring cylinder, when the ceramic powder materials in the two areas need to be poured into the stirring cylinder, an electric push rod I is shortened to drive a sliding cylinder to move downwards, at the moment, the sliding cylinder drives the front parts of the sliding plate to rotate downwards, at the moment, the two blocking pieces are not blocked at the front parts of the two areas, and the two ceramic powder materials fall into the stirring cylinder to mix; two kinds of ceramic powder can be added at one time, and the ceramic powder can be added for many times according to the variety number of the powder.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic diagram of an overall structure of an automated 5G base station ceramic filter production system according to the present invention;

FIG. 2 is a schematic diagram of the overall structure of an automated 5G base station ceramic filter production system according to the present invention;

FIG. 3 is a schematic structural view of a mixing drum;

FIG. 4 is a first schematic structural diagram of a material sliding plate;

FIG. 5 is a second schematic structural view of a material sliding plate;

FIG. 6 is a schematic structural view of a base plate;

FIG. 7 is a schematic view of the structure of a semi-cylindrical tank;

fig. 8 is a schematic structural view of the rectangular base.

In the figure: a mixing drum 1; a gantry 101; a stopper piece 102; a motor I103; the cross bars 104; a hinge post 105; a stirring rod 106; a lower side door 107; a retaining edge 108; a material sliding plate 2; a partition plate 201; a slide hole 202; a sliding cylinder 203; an electric push rod I204; an L-shaped frame 205; a base plate 3; an electric push rod II 301; a rear bracket 302; a tap lever 303; a motor II 304; a column 305; a spring pocket bar 306; a translation stage 307; a trapezoidal slide rail 308; a fastening screw 309; a semi-cylindrical case 4; a fixed shaft 401; a left bar 402; a long insertion hole 403; a shaft support 404; a heating wire 405; a lift-off plate 406; a motor III 407; a rectangular base 5; a trough 501; a briquetting 502; a lifting column 503; an electric push rod III 504; a pan beam 505; a motor IV 506; a cutter 507; a motor V508; wire guide slots 509.

Detailed Description

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on those shown in the drawings, and are used only for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present invention. Furthermore, the terms "first", "second", etc. are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first," "second," etc. may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless otherwise specified.

The first embodiment is as follows:

the following describes the present embodiment with reference to fig. 1 to 8, and the present invention relates to the field of filter production, and more specifically to an automatic 5G base station ceramic filter production system, which includes a mixing drum 1, a gantry 101, a baffle 102, a material sliding plate 2, a partition plate 201, a sliding hole 202, a sliding cylinder 203, an electric push rod I204, and an L-shaped frame 205.

The rear side fixedly connected with L shape frame 205 of churn 1, the articulated downside at smooth flitch 2 that connects in the upper end of L shape frame 205, equal fixedly connected with division board 201 in both ends and middle part about smooth flitch 2 upside, three division board 201 divide into two regions with smooth flitch 2, the upside fixedly connected with separation blade 102 of churn 1, two separation blade 102 of fixedly connected with on separation blade 102, the front portion in two regions on smooth flitch 2 is inserted respectively to the lower part of two separation blade 102, fixedly connected with electric putter I204 on L shape frame 205, the expansion end fixedly connected with smooth cylinder 203 of electric putter I204, the right side of smooth flitch 2 is provided with slide opening 202, smooth cylinder 203 sliding connection is on slide opening 202. When the ceramic powder mixing device is used, different ceramic powder is placed in two areas on the sliding plate 2 according to the required proportion respectively, the amount of the ceramic powder placed in the two areas is convenient to observe, the two blocking pieces 102 are respectively blocked at the front parts of the two areas, at the moment, the ceramic powder in the two areas cannot fall into the mixing drum 1, when the ceramic powder in the two areas needs to be poured into the mixing drum 1, the electric push rod I204 is shortened to drive the sliding cylinder 203 to move downwards, at the moment, the sliding cylinder 203 drives the front parts of the sliding plate 2 to rotate downwards, at the moment, the two blocking pieces 102 are not blocked at the front parts of the two areas any more, and the two ceramic powders fall into the mixing drum 1 to be; two kinds of ceramic powder can be added at one time, and the ceramic powder can be added for many times according to the variety number of the powder.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 8, the automatic 5G base station ceramic filter production system further includes a motor I103, a horizontal bar plate 104 and a stirring rod 106, the horizontal bar plate 104 is fixedly connected to the upper side of the stirring drum 1, the motor I103 is fixedly connected to the middle portion of the upper side of the horizontal bar plate 104, an output shaft of the motor I103 is inserted into the stirring drum 1, and the output shaft of the motor I103 is fixedly connected to a plurality of stirring rods 106. The motor I103 can drive the stirring rod 106 to rotate, so as to mix and stir a plurality of ceramic powders in the stirring cylinder 1.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 8, the automatic 5G base station ceramic filter production system further includes a hinge column 105, a lower side door 107 and a blocking edge 108, the hinge column 105 is fixedly connected to the lower portion of the right side of the mixing drum 1, the lower end of the hinge column 105 is hinged to the lower side door 107, the lower side door 107 covers the lower opening of the mixing drum 1, and the blocking edge 108 is fixedly connected to both the front end and the rear end of the upper side of the lower side door 107. The lower door 107 can rotate under the hinge post 105, and then the lower door 107 is rotated to control the opening and closing of the lower part of the mixing drum 1, after the lower door 107 is opened, the lower door 107 is changed to a state of low left and high right, the ceramic powder slides down from the lower door 107 to the left, and the blocking edge 108 on the lower door 107 is used for preventing the ceramic powder from spilling from the front end and the rear end of the lower door 107.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 8, the automatic 5G base station ceramic filter production system further includes a bottom plate 3, an electric push rod II301 and a rear bracket 302, the bottom plate 3 is fixedly connected with the rear bracket 302, the mixing drum 1 is fixedly connected to the upper end of the rear bracket 302, the upper side of the bottom plate 3 is fixedly connected with the electric push rod II301, and the movable end of the electric push rod II301 is supported on the lower side of the lower side door 107. When the electric pusher II301 is extended, the lower door 107 is pressed against the lower part of the mixer drum 1 to close the mixer drum 1. When the electric push rod II301 is shortened, the lower side door 107 is opened due to the gravity of the ceramic powder, and the ceramic powder slides down along the lower side door 107.

The fifth concrete implementation mode:

the present embodiment is described below with reference to fig. 1 to 8, the automatic 5G base station ceramic filter production system further includes a semi-cylindrical case 4, a fixing shaft 401, a shaft bracket 404, heating wires 405, a lifting plate 406, and a motor III407, the shaft bracket 404 is fixedly connected to the upper side of the base plate 3, the fixing shaft 401 is rotatably connected to the upper portion of the shaft bracket 404, the semi-cylindrical case 4 is fixedly connected to the right end of the fixing shaft 401, the motor III407 is fixedly connected to the right side of the semi-cylindrical case 4, an output shaft of the motor III407 is inserted into the semi-cylindrical case 4, the lifting plate 406 is fixedly connected to an output shaft of the motor III407, the plurality of heating wires 405 are disposed on the outer side of the semi-cylindrical case 4, and the semi-. The ceramic powder sliding down along the lower side door 107 falls into the semi-cylindrical box 4, the heating wire 405 on the semi-cylindrical box 4 dries the ceramic powder, and the motor III407 drives the lifting plate 406 to rotate to continuously lift the ceramic powder, so that the drying speed of the ceramic powder is accelerated. The semi-cylindrical box 4 and the ceramic powder in the semi-cylindrical box 4 can rotate through the fixed shaft 401, so that the front and back swinging motion of the semi-cylindrical box 4 and the ceramic powder in the semi-cylindrical box 4 is realized, and the drying speed of the ceramic powder is further accelerated.

The sixth specific implementation mode:

the present embodiment is described below with reference to fig. 1 to 8, where the automatic 5G base station ceramic filter production system further includes a vertical column 305, a spring loop bar 306, a left side bar 402 and a long insertion hole 403, the right end of the fixing shaft 401 is fixedly connected with the left side bar 402, the left side bar 402 is provided with the long insertion hole 403, both front and rear ends of the spring loop bar 306 are fixedly connected with the vertical column 305, both lower ends of the two vertical columns 305 are fixedly connected to the bottom plate 3, the spring loop bar 306 passes through the long insertion hole 403, both front and rear portions of the spring loop bar 306 are sleeved with compression springs, and the two compression springs are respectively located on both front and rear sides of the left side bar 402. When the semi-cylindrical case 4 and the ceramic powder in the semi-cylindrical case 4 rotate through the fixed shaft 401, the left side rod 402 also rotates along with the fixed shaft, when the left side rod 402 rotates, one of the compression springs on the spring sleeve rods 306 is compressed, and the two spring sleeve rods 306 can return the left side rod 402 and the semi-cylindrical case 4 to the original position.

The seventh embodiment:

the present embodiment is described below with reference to fig. 1 to 8, the automatic 5G base station ceramic filter production system further includes a poke rod 303, a motor II304, a translation frame 307, a trapezoidal slide rail 308 and a fastening screw 309, the left portion of the bottom plate 3 is provided with the trapezoidal slide rail 308 arranged in the front-back direction, the lower portion of the translation frame 307 is slidably connected to the trapezoidal slide rail 308, the lower portion of the translation frame 307 is connected to the fastening screw 309 through a thread, the fastening screw 309 abuts against the trapezoidal slide rail 308, the upper portion of the translation frame 307 is fixedly connected to the motor II304, an output shaft of the motor II304 is fixedly connected to the poke rod 303, and the poke rod 303 is located in front of the semi-cylindrical. Motor II304 drives poker rod 303 and rotates, and poker rod 303 stirs cylinder case 4 and constantly rotates through fixed axle 401 and rocks for ceramic powder's stoving speed, two spring sleeve poles 306 constantly return left side pole 402 and half cylinder case 4 to the normal position, and then realize that cylinder case 4 constantly rotates vibrations through fixed axle 401, further accelerates ceramic powder's stoving speed.

The specific implementation mode is eight:

the present embodiment is described below with reference to fig. 1 to 8, where the automatic 5G base station ceramic filter production system further includes a rectangular base 5, a trough 501, a pressing block 502, a lifting column 503, an electric push rod III504, a horizontal rotation beam 505, a motor IV506, and a wire guide 509, the rectangular base 5 is fixedly connected to the front portion of the bottom plate 3, the trough 501 is provided on the rectangular base 5, the three wire guide 509 parallel to each other are provided on the front portion of the trough 501, the motor IV506 is fixedly connected to the right end of the rectangular base 5, the horizontal rotation beam 505 is fixedly connected to an output shaft of the motor IV506, the lifting column 503 is vertically and slidably connected to the left end of the horizontal rotation beam 505, the pressing block 502 is fixedly connected to the lower end of the lifting column 503, the electric push rod III504 is fixedly connected to the horizontal rotation beam 505, and the movable end of the electric push rod III 504. The dried ceramic powder is poured into the trough 501, metal columns are placed at the positions of the three wire grooves 509, one ends of the three metal columns are buried in the ceramic powder in the trough 501, the electric push rod III504 drives the pressing block 502 and the lifting column 503 to move downwards, the ceramic powder in the trough 501 is compacted and shaped, and the three metal columns and the compacted and shaped ceramic powder are combined to form the 5G base station ceramic filter. The motor IV506 can drive the translation beam 505 to rotate, so as to drive the pressing block 502 to rotate, and the pressing block 502 can be moved away when needed.

The specific implementation method nine:

the embodiment is described below with reference to fig. 1 to 8, and the automatic 5G base station ceramic filter production system further includes a cutter 507 and a motor V508, the motor V508 is fixedly connected to the front side of the rectangular seat 5, the cutter 507 is fixedly connected to an output shaft of the motor V508, and the cutter 507 is attached to the front end face of the rectangular seat 5. When the motor V508 drives the cutter 507 to rotate, the redundant part of the metal column can be cut off.

The working principle of the invention is as follows: when the ceramic powder mixing device is used, different ceramic powder is placed in two areas on the sliding plate 2 according to the required proportion respectively, the amount of the ceramic powder placed in the two areas is convenient to observe, the two blocking pieces 102 are respectively blocked at the front parts of the two areas, at the moment, the ceramic powder in the two areas cannot fall into the mixing drum 1, when the ceramic powder in the two areas needs to be poured into the mixing drum 1, the electric push rod I204 is shortened to drive the sliding cylinder 203 to move downwards, at the moment, the sliding cylinder 203 drives the front parts of the sliding plate 2 to rotate downwards, at the moment, the two blocking pieces 102 are not blocked at the front parts of the two areas any more, and the two ceramic powders fall into the mixing drum 1 to be; two kinds of ceramic powder can be added at one time, and the ceramic powder can be added for many times according to the variety number of the powder. The motor I103 can drive the stirring rod 106 to rotate, so as to mix and stir a plurality of ceramic powders in the stirring cylinder 1. The lower door 107 can rotate under the hinge post 105, and then the lower door 107 is rotated to control the opening and closing of the lower part of the mixing drum 1, after the lower door 107 is opened, the lower door 107 is changed to a state of low left and high right, the ceramic powder slides down from the lower door 107 to the left, and the blocking edge 108 on the lower door 107 is used for preventing the ceramic powder from spilling from the front end and the rear end of the lower door 107. When the electric pusher II301 is extended, the lower door 107 is pressed against the lower part of the mixer drum 1 to close the mixer drum 1. When the electric push rod II301 is shortened, the lower side door 107 is opened due to the gravity of the ceramic powder, and the ceramic powder slides down along the lower side door 107. The ceramic powder sliding down along the lower side door 107 falls into the semi-cylindrical box 4, the heating wire 405 on the semi-cylindrical box 4 dries the ceramic powder, and the motor III407 drives the lifting plate 406 to rotate to continuously lift the ceramic powder, so that the drying speed of the ceramic powder is accelerated. The semi-cylindrical box 4 and the ceramic powder in the semi-cylindrical box 4 can rotate through the fixed shaft 401, so that the front and back swinging motion of the semi-cylindrical box 4 and the ceramic powder in the semi-cylindrical box 4 is realized, and the drying speed of the ceramic powder is further accelerated. When the semi-cylindrical case 4 and the ceramic powder in the semi-cylindrical case 4 rotate through the fixed shaft 401, the left side rod 402 also rotates along with the fixed shaft, when the left side rod 402 rotates, one of the compression springs on the spring sleeve rods 306 is compressed, and the two spring sleeve rods 306 can return the left side rod 402 and the semi-cylindrical case 4 to the original position. Motor II304 drives poker rod 303 and rotates, and poker rod 303 stirs cylinder case 4 and constantly rotates through fixed axle 401 and rocks for ceramic powder's stoving speed, two spring housing bars 306 constantly return left side pole 402 and half cylinder case 4 to the normal position, and then realize that cylinder case 4 constantly rotates vibrations through fixed axle 401, further accelerates ceramic powder's stoving speed. The dried ceramic powder is poured into the trough 501, metal columns are placed at the positions of the three wire grooves 509, one ends of the three metal columns are buried in the ceramic powder in the trough 501, the electric push rod III504 drives the pressing block 502 and the lifting column 503 to move downwards, the ceramic powder in the trough 501 is compacted and shaped, and the three metal columns and the compacted and shaped ceramic powder are combined to form the 5G base station ceramic filter. The motor IV506 can drive the translation beam 505 to rotate, so as to drive the pressing block 502 to rotate, and the pressing block 502 can be moved away when needed. When the motor V508 drives the cutter 507 to rotate, the redundant part of the metal column can be cut off.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (2)

1. The utility model provides an automatic change 5G basic station ceramic filter production system, includes churn (1), door shape frame (101), separation blade (102), smooth flitch (2), division board (201), slide opening (202), smooth cylinder (203), electric putter I (204) and L shape frame (205), its characterized in that: the rear side of the mixing drum (1) is fixedly connected with an L-shaped frame (205), the upper end of the L-shaped frame (205) is hinged to the lower side of the material sliding plate (2), the left end, the right end and the middle of the upper side of the material sliding plate (2) are fixedly connected with partition plates (201), the material sliding plate (2) is divided into two areas by the three partition plates (201), the upper side of the mixing drum (1) is fixedly connected with a baffle plate (102), the two baffle plates (102) are fixedly connected onto the baffle plate (102), the lower parts of the two baffle plates (102) are respectively inserted into the front parts of the two areas on the material sliding plate (2), an electric push rod I (204) is fixedly connected onto the L-shaped frame (205), a sliding cylinder (203) is fixedly connected onto the movable end of the electric push rod I (204), a sliding hole (202) is formed in the right side of the material;

the automatic 5G base station ceramic filter production system further comprises a motor I (103), a transverse strip plate (104) and stirring rods (106), wherein the transverse strip plate (104) is fixedly connected to the upper side of the stirring cylinder (1), the motor I (103) is fixedly connected to the middle of the upper side of the transverse strip plate (104), an output shaft of the motor I (103) is inserted into the stirring cylinder (1), and a plurality of stirring rods (106) are fixedly connected to the output shaft of the motor I (103);

the automatic 5G base station ceramic filter production system further comprises a hinge column (105), a lower side door (107) and a blocking edge (108), the hinge column (105) is fixedly connected to the lower portion of the right side of the mixing drum (1), the lower end of the hinge column (105) is hinged to the lower side door (107), the lower side door (107) covers the lower opening of the mixing drum (1), and the blocking edge (108) is fixedly connected to the front end and the rear end of the upper side of the lower side door (107);

the automatic 5G base station ceramic filter production system further comprises a bottom plate (3), an electric push rod II (301) and a rear support (302), the rear support (302) is fixedly connected to the bottom plate (3), the mixing drum (1) is fixedly connected to the upper end of the rear support (302), the electric push rod II (301) is fixedly connected to the upper side of the bottom plate (3), and the movable end of the electric push rod II (301) is propped against the lower side of the lower side door (107);

the automatic 5G base station ceramic filter production system further comprises a semi-cylindrical box (4), a fixed shaft (401), a shaft support (404), heating wires (405), a lifting plate (406) and a motor III (407), wherein the shaft support (404) is fixedly connected to the upper side of the base plate (3), the upper portion of the shaft support (404) is rotatably connected with the fixed shaft (401), the semi-cylindrical box (4) is fixedly connected to the right end of the fixed shaft (401), the right side of the semi-cylindrical box (4) is fixedly connected with the motor III (407), an output shaft of the motor III (407) is inserted into the semi-cylindrical box (4), the lifting plate (406) is fixedly connected to an output shaft of the motor III (407), the plurality of heating wires (405) are arranged on the outer side of the semi-cylindrical box (4), and the semi-cylindrical box (4) is located on the lower left;

the automatic 5G base station ceramic filter production system further comprises upright posts (305), spring sleeve rods (306), a left side rod (402) and a long jack (403), the right end of the fixed shaft (401) is fixedly connected with the left side rod (402), the left side rod (402) is provided with the long jack (403), the front end and the rear end of each spring sleeve rod (306) are fixedly connected with the upright posts (305), the lower ends of the two upright posts (305) are fixedly connected to the bottom plate (3), each spring sleeve rod (306) penetrates through the long jack (403), the front part and the rear part of each spring sleeve rod (306) are sleeved with compression springs, and the two compression springs are respectively positioned on the front side and the rear side of the left side rod (402);

the automatic 5G base station ceramic filter production system further comprises a poke rod (303), a motor II (304), a translation frame (307), a trapezoidal sliding rail (308) and fastening screws (309), the trapezoidal sliding rail (308) arranged in the front-back direction is arranged at the left part of the bottom plate (3), the lower part of the translation frame (307) is connected to the trapezoidal sliding rail (308) in a sliding mode, the lower part of the translation frame (307) is connected with the fastening screws (309) through threads, the fastening screws (309) are tightly propped against the trapezoidal sliding rail (308), the upper part of the translation frame (307) is fixedly connected with the motor II (304), a poke rod (303) is fixedly connected to an output shaft of the motor II (304), and the poke rod (303) is located in front of the semi-cylindrical box (4);

the automatic 5G base station ceramic filter production system also comprises a rectangular base (5), a trough (501), a pressing block (502), a lifting column (503), an electric push rod III (504), a horizontal rotating beam (505), a motor IV (506) and a wire guide groove (509), rectangular seat (5) fixed connection is in the front portion of bottom plate (3), be provided with silo (501) on rectangular seat (5), the front portion of silo (501) is provided with three metallic channel (509) that are parallel to each other, the right-hand member fixedly connected with motor IV (506) of rectangular seat (5), fixedly connected with tie-turn beam (505) on the output shaft of motor IV (506), the vertical sliding connection of left end of tie-turn beam (505) has lift post (503), the lower extreme fixedly connected with briquetting (502) of lift post (503), fixedly connected with electric putter III (504) on tie-turn beam (505), the expansion end fixed connection of electric putter III (504) is on the upper portion of lift post (503).

2. The automated 5G base station ceramic filter production system of claim 1, wherein: the automatic 5G base station ceramic filter production system further comprises a cutter (507) and a motor V (508), the front side of the rectangular base (5) is fixedly connected with the motor V (508), the output shaft of the motor V (508) is fixedly connected with the cutter (507), and the cutter (507) is attached to the front end face of the rectangular base (5).

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