CN111002433A

CN111002433A - White stick shaping production and processing equipment of resistance pottery

Info

Publication number: CN111002433A
Application number: CN201911205603.4A
Authority: CN
Inventors: 周建发
Original assignee: 周建发
Current assignee: XUZHOU CONNOR HI-TECH MATERIALS SCIENCE AND TECHNOLOGY Co.,Ltd.
Priority date: 2019-11-29
Filing date: 2019-11-29
Publication date: 2020-04-14
Anticipated expiration: 2039-11-29
Also published as: CN111002433B

Abstract

The invention discloses a resistor ceramic white bar forming production processing device which structurally comprises a rack, a discharge port, a forming processing mechanism, a driving box and a drying box, wherein the discharge port is arranged at the front end of the rack; the injection pushing mechanism is arranged above the forming mechanism and is in close contact with the inner wall during demoulding, so that the material is prevented from falling off due to damage of corners, the excess residual materials can be scraped and cleaned, the residual materials are prevented from being mixed in the next injection forming, and the forming uniformity of the ceramic white bar is improved.

Description

White stick shaping production and processing equipment of resistance pottery

Technical Field

The invention belongs to the field of resistance ceramic processing, and particularly relates to resistance ceramic white rod forming production processing equipment.

Background

The white resistance ceramic rod is used for various coating resistors and wire-wound resistor substrates, is used as a substrate of a high-power resistor, and along with the application universality of the material properties, the application of people to the white resistance ceramic rod is more extensive, and the batch production is carried out, so that the white resistance ceramic rod forming production and processing equipment is needed to accelerate the production speed of the white resistance ceramic rod, but the prior art has the following defects:

the ceramic white rod is subjected to demoulding after being pressed and formed, and the ceramic white rod is easy to damage corners when being pushed out and demoulded, so that the material falls off and remains in a mould, and is combined with the residual material in the next production and processing, and the ceramic white rod is irregularly formed due to different temperatures, so that the ceramic white rod is not uniformly formed.

Therefore, the application provides a resistor ceramic white bar forming production and processing device which improves the defects.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide resistor ceramic white rod forming production and processing equipment to solve the problems that in the prior art, after ceramic white rods are subjected to compression forming, demolding treatment is needed, corner damage is easily caused when the ceramic white rods are pushed out and demolded, the materials fall off and then remain in a mold, the materials are combined with the remaining materials in the next production and processing, and the ceramic white rods are irregularly formed due to different temperatures, so that the ceramic white rods are not uniformly formed.

In order to achieve the purpose, the invention is realized by the following technical scheme: a resistor ceramic white bar forming production processing device structurally comprises a rack, a discharge port, a forming processing mechanism, a driving box and a drying box, wherein the discharge port is arranged at the front end of the rack and is of an integrated structure; the molding mechanism comprises a frame, a molding mechanism, an injection pushing mechanism, guide shafts and push rods, wherein the molding mechanism is installed on the inner side of the frame and is connected with the frame through hinges, the injection pushing mechanism is horizontally arranged above the molding mechanism, the guide shafts are vertically installed at the upper end of the frame and penetrate through the two sides of the injection pushing mechanism, and the push rods are vertically installed at the upper end of the injection pushing mechanism and are connected with the injection pushing mechanism through machinery.

The invention is further improved, the forming mechanism comprises a forming structure, mounting blocks, a connecting rod, a ferrule and a rotating rod, the forming structure is mounted between the mounting blocks and is connected by a hinge, the connecting rod is fixedly connected to the outer sides of the mounting blocks, the ferrule is sleeved on the outer sides of the rotating rod and is clamped, and the connecting rod is fixedly mounted on the outer sides of the ferrule and is connected by a bolt.

The invention is further improved, the forming structure comprises a bottom plate, a sliding structure, a forming die and an inner groove, the bottom plate is horizontally arranged at the lower end of the sliding structure and is mechanically connected, the sliding structure is embedded into the lower end of the inner side of the forming die, and the inner groove penetrates through the inner side of the forming die.

The invention is further improved, the sliding structure comprises a thread block, a screw rod, a machine head, a motor and a circuit control device, the thread block is sleeved on the outer side of the screw rod and meshed with the screw rod, the right side of the screw rod is embedded and installed on the inner side of the machine head, the motor is arranged on the inner side of the machine head, the circuit control device is located on the inner side of the machine head and used for controlling the motor, and the right side of the screw rod is mechanically connected with the left side of the motor.

The circuit control device is further improved, the circuit control device comprises a power supply module, a light sensing module, a micro-processing control unit and a motor driving module, the power supply module is respectively and electrically connected with a motor and the micro-processing control unit through leads and provides working voltage for the motor and the micro-processing control unit, the light sensing module detects the brightness or darkness of the outside and sends out corresponding signals, the micro-processing control unit is used for controlling the motor driving module to start the motor and sending out signals for forward rotation or reverse rotation of the motor to the micro-processing control unit according to output signals of the light sensing module, and the motor driving module controls the forward rotation or reverse rotation of the motor according to the output signals for forward rotation or reverse rotation of the motor of the micro-processing control unit.

The injection pushing mechanism comprises a panel, sliding grooves, an injection tube and a downward pushing structure, wherein the sliding grooves penetrate through two sides of the panel, the injection tube is vertically arranged on the right side of the lower end of the panel, and the downward pushing structure is embedded and arranged on the left side of the inner side of the panel.

The invention is further improved, the downward pressing and pushing structure comprises a pushing cleaning structure, a fixed rod, a shielding sleeve and a spring, the pushing cleaning structure is vertically arranged at the lower end of the fixed rod, the fixed rod is arranged at the inner side of the shielding sleeve, the shielding sleeve is embedded at the inner side of the panel and is movably connected, and the spring is arranged at the inner side of the panel and the lower end of the spring is abutted against the upper end of the shielding sleeve.

The invention is further improved, the pushing-out cleaning structure comprises a supporting rod, a pushing disc, a net brush and a scraper, the supporting rod is vertically arranged at the upper end of the pushing disc and connected to the lower end of the fixing rod, the net brush is sleeved on the outer side of the pushing disc, and the scraper is arranged at the upper end of the outer side of the pushing disc in a surrounding mode and arranged above the net brush.

According to the technical scheme, the production and processing equipment for forming the white resistance ceramic rod has the following beneficial effects:

the injection pushing mechanism is arranged above the forming mechanism, the bottom plate is opened, the shielding sleeve is pushed into the inner side of the panel by continuous downward pressing, the spring is compressed, the pushing cleaning structure enters the inner groove which is formed, the ceramic white rod is pushed out and is sent out from the discharge hole, the scraper is used for scraping residues on the inner wall while pushing, the driving box retracts the push rod while the right-side forming structure is filled with raw materials and the left-side forming structure ceramic white rod is pushed out, the injection pushing mechanism is integrally retracted at the moment, the inner groove is cleaned again by the net brush, the injection pushing mechanism is tightly contacted with the inner wall during demolding, the materials are prevented from falling off due to damage of corners, the excessive residual materials can be scraped and cleaned, the residual materials are prevented from being mixed in the next injection forming, and the uniformity of the ceramic white rod forming is improved.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

FIG. 1 is a schematic structural diagram of a resistor ceramic white bar molding production and processing device according to the present invention;

FIG. 2 is a schematic structural view of the forming mechanism of the present invention;

FIG. 3 is a schematic front view of the forming mechanism of the present invention;

FIG. 4 is a schematic side view of the forming mechanism of the present invention;

FIG. 5 is a schematic structural view of a forming structure according to the present invention;

FIG. 6 is a schematic structural view of a sliding structure according to the present invention;

FIG. 7 is a circuit schematic of the circuit control device of the present invention;

FIG. 8 is a schematic front view of the injection ejector mechanism of the present invention;

FIG. 9 is a schematic side view of the injection ejector mechanism of the present invention;

FIG. 10 is a schematic view of a push-down structure according to the present invention;

FIG. 11 is a schematic top view of a push-out cleaning structure according to the present invention;

fig. 12 is a front view of a cleaning structure according to the present invention.

In the figure: a frame-1, a discharge port-2, a forming processing mechanism-3, a driving box-4, a drying box-5, a frame-31, a forming mechanism-32, an injection push-out mechanism-33, a guide shaft-34, a push rod-35, a forming structure-321, a mounting block-322, a connecting rod-323, a ferrule-324, a rotating rod-325, a bottom plate-21 a, a sliding structure-21 b, a forming die-21 c, an internal groove-21 d, a thread block-b 1, a screw rod-b 2, a machine head-b 3, a motor-b 4, a circuit control device-b 5, a power supply module-b 51, a light sensing module-b 52, a microprocessing control unit-b 53, a motor driving module-b 54, a panel-331, a chute-332, an injection tube-333, a motor driving module-b 54, push-down push-out structure-334, push-out cleaning structure-34 a, fixed rod-34 b, shielding sleeve-34 c, spring-34 d, supporting rod-a 1, push disc-a 2, net brush-a 3 and scraper-a 4.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

Referring to fig. 1-8, the embodiments of the present invention are as follows:

the structure of the drying machine comprises a rack 1, a discharge port 2, a forming and processing mechanism 3, a driving box 4 and a drying box 5, wherein the discharge port 2 is arranged at the front end of the rack 1 and is of an integrated structure, the forming and processing mechanism 3 is horizontally embedded and installed at the upper end of the rack 1 and is mechanically connected, the forming and processing mechanism 3 is installed at the lower end of the driving box 4 and is mechanically connected to the upper end of the rack 1, and the drying box 5 is arranged at the upper end of the rack 1 and is positioned at the rear end of the forming and processing mechanism 3; the molding mechanism 3 includes a frame 31, a molding mechanism 32, an injection pushing mechanism 33, a guide shaft 34, and a push rod 35, the molding mechanism 32 is installed inside the frame 31 and connected by a hinge, the injection pushing mechanism 33 is horizontally disposed above the molding mechanism 32, the guide shaft 34 is vertically installed on the upper end of the frame 31 and penetrates through two sides of the injection pushing mechanism 33, and the push rod 35 is vertically installed on the upper end of the injection pushing mechanism 33 and connected by a machine.

Referring to fig. 3-4, the molding mechanism 32 includes a molding structure 321, mounting blocks 322, a connecting rod 323, a collar 324, and a rotating rod 325, the molding structure 321 is mounted between the mounting blocks 322 and is connected by a hinge, the molding structure 321 is always in a horizontal state under the influence of gravity, the connecting rod 323 is fixedly connected to the outside of the mounting blocks 322, the collar 324 is sleeved on the outside of the rotating rod 325 and is clamped, the connecting rod 323 is fixedly mounted to the outside of the collar 324 and is connected by a bolt, the rotating rod 325 rotates according to the time of injecting material, the ceramic white rod is manufactured on the molding structure 321, is dried and molded along with the rotation, and is then pushed out.

Referring to fig. 5, the forming structure 321 includes a bottom plate 21a, a sliding structure 21b, a forming mold 21c, and an inner groove 21d, the bottom plate 21a is horizontally mounted at the lower end of the sliding structure 21b and is mechanically connected, the sliding structure 21b is embedded in the lower end of the inner side of the forming mold 21c, the inner groove 21d penetrates the inner side of the forming mold 21c, the bottom plate 21a is in a closed state during injection, and the bottom plate 21a is driven to open by the sliding structure 21b during pushing.

Referring to fig. 6, the sliding structure 21b includes a screw block b1, a screw b2, a machine head b3, a motor b4, and a circuit control device b5, the screw block b1 is sleeved outside the screw b2 and engaged with the screw b2, the right side of the screw b2 is embedded inside the machine head b3, the motor b4 is disposed inside the machine head b3, the circuit control device b5 is located inside the machine head b3 and used for controlling the motor b4, the right side of the screw b2 is mechanically connected with the left side of the motor b4, and the motor b4 is used for driving the screw b2 to rotate forward or backward to drive the screw block b1 to close or open the bottom plate 21 a.

Referring to fig. 7, the circuit control device b5 includes a power module b51, a light sensing module b52, a microprocessor control unit b53, a motor driving module b54, the power supply module b51 is respectively connected with the motor b4 and the micro-processing control unit b53 through leads and provides working voltage for the motor b4 and the micro-processing control unit b53, the light sensing module b52 sends out corresponding signal when detecting the light or dark outside, the micro-processing control unit b53 is used for controlling the motor driving module b54 to start the motor b4 and sending out the signal of the forward rotation or reverse rotation of the motor to the micro-processing control unit b53 according to the output signal of the light sensing module b52, the motor driving module b54 controls the motor b4 to rotate forward or backward according to the motor forward or backward rotation output signal of the micro-processing control unit b53, the forward rotation signal is sent out when light exists and the reverse rotation signal is sent out when no light exists, and the motor driving module b54 only provides the voltage for the motor b4 for 3 seconds at a time.

Referring to fig. 8 to 9, the injection pushing-out mechanism 33 includes a panel 331, a sliding groove 332, an injection tube 333, and a push-down pushing-out structure 334, wherein the sliding groove 332 penetrates through two sides of the panel 331, the injection tube 333 is vertically installed at the right side of the lower end of the panel 331, the push-down pushing-out structure 334 is embedded at the left side of the inner side of the panel 331, and the injection tube 333 and the push-down pushing-out structure 334 are pushed down to inject the raw material and push out the formed ceramic white bar, respectively.

Referring to fig. 10, the push-down pushing structure 334 includes a pushing-out cleaning structure 34a, a fixing rod 34b, a shielding sleeve 34c, and a spring 34d, the pushing-out cleaning structure 34a is vertically installed at the lower end of the fixing rod 34b, the fixing rod 34b is installed inside the shielding sleeve 34c, the shielding sleeve 34c is embedded inside the panel 331 and movably connected, the spring 34d is installed inside the panel 331 and the lower end thereof abuts against the upper end of the shielding sleeve 34c, the shielding sleeve 34c first abuts against the upper end of the forming mold 21c, so that the light sensing module b52 cannot sense light, the bottom plate 21a is opened, and the pushing-out cleaning structure 34a is used to move out and clean the ceramic white bar.

Referring to fig. 11 to 12, the pushing-out cleaning structure 34a includes a supporting rod a1, a pushing plate a2, a net brush a3, and a scraper a4, the supporting rod a1 is vertically installed at the upper end of the pushing plate a2 and connected to the lower end of the fixing rod 34b, the net brush a3 is sleeved outside the pushing plate a2, and the scraper a4 is installed around the upper end of the pushing plate a2 and above the net brush a3, so as to scrape off the inner groove 21d and brush off the inner groove, thereby keeping the inner side clean.

Based on the above embodiment, the specific working principle is as follows:

the push rod 35 is pushed by the driving box 4 to move downwards, at this time, the injection pushing mechanism 33 moves downwards along the guide shaft 34, when the injection pushing mechanism 33 contacts the molding mechanism 32, the injection tube 333 injects the raw material to the right-side molding structure 321, and the light sensing module b52 detects the light at this time, and sends a signal to the microprocessing control unit b53 and outputs a motor forward rotation signal to the motor driving module b54, so that the motor b4 rotates forwards, the screw b2 is driven to rotate to engage the thread block b1, at this time, the bottom plate 21a is closed, and the injected raw material stays in the inner groove 21d for molding; meanwhile, the whole injection pushing-out mechanism 33 is pressed downwards to contact the forming mechanism 32, the pushing-out structure 334 is pressed downwards to contact the left forming structure 321, the shielding sleeve 34c blocks the light of the light sensing module b52, the light sensing module b52 cannot detect the light and sends a signal to the microprocessing control unit b53, a motor reversal signal is output to the motor driving module b54, the motor b4 is reversed to drive the screw b2 to rotate and engage the thread block b1, the bottom plate 21a is opened, the shielding sleeve 34c is pushed into the panel 331 and compresses the spring 34d by continuous pressing, the cleaning structure 34a is pushed into the formed inner groove 21d, the ceramic white rod is pushed out from the discharge hole 2, residues on the inner wall are pushed out by the scraper a4 while pushing out, and the right forming structure 321 is injected with raw materials and the left forming structure 321 is scraped out, the driving box 4 will withdraw the push rod 35, at this time, the injection push-out mechanism 33 will be withdrawn as a whole and the net brush a3 will clean the inner groove 21d again, after being retracted, the rotating rod 325 will rotate clockwise one by one, so that the forming structure 321 which has just pushed out the ceramic white bar enters the raw material injection station, the next forming structure 321 which has completed forming will enter the ceramic white bar push-out station, the forming structure 321 which has just injected the raw material enters the inner side of the frame 31 for drying, and thus the material injection, drying and pushing are performed in a circulating manner.

The invention solves the problems that in the prior art, after the ceramic white rod is pressed and formed, demoulding treatment is needed, the ceramic white rod is easy to cause damage to corners when being pushed and demoulded, so that the material falls off and remains in a mould, the ceramic white rod is combined with the remaining material in the next production and processing, and the forming is irregular due to different temperatures, so that the ceramic white rod is formed unevenly, through the mutual combination of the components, an injection pushing mechanism is arranged above the forming mechanism, a bottom plate is opened, a shielding sleeve is pushed into the inner side of a panel and a spring is compressed by continuous downward pressing, a pushing cleaning structure enters an inner groove which is formed, the ceramic white rod is pushed out from a discharge port, residues on the inner wall are scraped by a scraper while the ceramic white rod is pushed out, and when the injection of the raw material into a right-side forming structure and the pushing of the ceramic white rod of a left-side forming structure are completed, the push rod will be withdrawed to the drive case, and injection pushing mechanism is whole to be withdrawed this moment and the net brush will clean the inside groove once more, with the in close contact with of inner wall when the drawing of patterns, prevents to cause the damage of corner to make the material drop to can strike off and clear up unnecessary defective material, mix with the defective material in preventing the injection molding of next time, improved the fashioned homogeneity of ceramic white stick.

While there have been shown and described what are at present considered the fundamental principles and essential features of the invention and its advantages, it will be apparent to those skilled in the art that the invention is not limited to the details of the foregoing exemplary embodiments, but is capable of other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims

1. A resistor ceramic white bar forming production and processing device structurally comprises a rack (1), a discharge port (2), a forming and processing mechanism (3), a driving box (4) and a drying box (5), wherein the discharge port (2) is arranged at the front end of the rack (1), the forming and processing mechanism (3) is horizontally embedded and mounted at the upper end of the rack (1), the forming and processing mechanism (3) is mounted at the lower end of the driving box (4), and the drying box (5) is arranged at the upper end of the rack (1); the method is characterized in that:

the molding mechanism (3) comprises a frame (31), a molding mechanism (32), an injection pushing mechanism (33), a guide shaft (34) and a push rod (35), wherein the molding mechanism (32) is installed on the inner side of the frame (31), the injection pushing mechanism (33) is horizontally arranged above the molding mechanism (32), the guide shaft (34) is vertically installed at the upper end of the frame (31), and the push rod (35) is vertically installed at the upper end of the injection pushing mechanism (33).

2. The resistance ceramic white rod forming production processing equipment according to claim 1, wherein: forming mechanism (32) include forming structure (321), installation piece (322), connecting rod (323), lasso (324), dwang (325), forming structure (321) are installed between installation piece (322), connecting rod (323) fixed connection is in the installation piece (322) outside, dwang (325) outside is located to lasso (324) cover, connecting rod (323) fixed mounting is in lasso (324) outside.

3. The resistance ceramic white rod forming production processing equipment according to claim 2, characterized in that: the forming structure (321) comprises a bottom plate (21a), a sliding structure (21b), a forming die (21c) and an inner groove (21d), wherein the bottom plate (21a) is horizontally arranged at the lower end of the sliding structure (21b), the sliding structure (21b) is embedded into the lower end of the inner side of the forming die (21c), and the inner groove (21d) penetrates through the inner side of the forming die (21 c).

4. The resistance ceramic white rod forming production processing equipment according to claim 3, characterized in that: sliding structure (21b) includes screw block (b1), screw rod (b2), aircraft nose (b3), motor (b4), circuit control device (b5), screw rod (b2) outside is located to screw block (b1) cover, the embedding of screw rod (b2) right side is installed in aircraft nose (b3) inboard, aircraft nose (b3) inboard is located in motor (b4), circuit control device (b5) are located aircraft nose (b3) inboard and are used for controlling motor (b4), mechanical connection is adopted on screw rod (b2) right side and motor (b4) left side.

5. The resistance ceramic white rod forming production processing equipment according to claim 4, wherein: the circuit control device (b5) comprises a power supply module (b51), a light sensing module (b52), a micro-processing control unit (b53) and a motor driving module (b54), wherein the power supply module (b51) is respectively electrically connected with a motor (b4) and the micro-processing control unit (b53) through leads and provides working voltage for the motor (b4) and the micro-processing control unit (b53), the light sensing module (b52) detects the brightness or darkness of the outside world and sends corresponding signals, the micro-processing control unit (b53) is used for controlling the motor driving module (b54) to start the motor (b4) and send signals for forward rotation or reverse rotation of the motor to the micro-processing control unit (b53) according to output signals of the light sensing module (b52), and the motor driving module (b54) controls the motor (b4) according to the signals for forward rotation or reverse rotation of the motor of the micro-processing control unit (b 53).

6. The resistance ceramic white rod forming production processing equipment according to claim 1, wherein: the injection push-out mechanism (33) comprises a panel (331), a sliding groove (332), an injection tube (333) and a push-down structure (334), wherein the sliding groove (332) penetrates through two sides of the panel (331), the injection tube (333) is vertically arranged on the right side of the lower end of the panel (331), and the push-down structure (334) is embedded in the left side of the inner side of the panel (331).

7. The resistance ceramic white rod forming production processing equipment according to claim 6, wherein: push down ejecting structure (334) including pushing out clean structure (34a), dead lever (34b), cover (34c), spring (34d), push out clean structure (34a) and vertically install in dead lever (34b) lower extreme, cover (34c) inboard is located in dead lever (34b), cover (34c) embedding in panel (331) inboard, panel (331) inboard is located in spring (34 d).

8. The resistance ceramic white rod forming production processing equipment according to claim 7, wherein: the push-out cleaning structure (34a) comprises a supporting rod (a1), a push disc (a2), a net brush (a3) and a scraper (a4), wherein the supporting rod (a1) is vertically arranged at the upper end of the push disc (a2), the outer side of the push disc (a2) is sleeved with the net brush (a3), and the scraper (a4) is arranged at the upper end of the outer side of the push disc (a2) in a surrounding mode.