CN111850661A - Rotary type electroplating mechanical cantilever conductive mechanism - Google Patents

Abstract

The invention discloses a rotary type electroplating machinery cantilever conductive mechanism, which structurally comprises a middle connecting rod, a connecting arm, a supporting rod, a base and a clamping mechanism, wherein the middle connecting rod is movably clamped with the connecting arm, the connecting arm is connected with the upper end of the supporting rod, the supporting rod is welded with the base, the clamping mechanism is arranged at the front end position of the middle connecting rod, the clamping head is driven to rotate by the rotating disc, the outer disc can rotate along with the rotating disc, and the stress block can be contracted inwards by the extrusion on the stress block when the outer disc rotates, thereby the integration disc can not rotate synchronously along with the rotation of the outer disc, so that the conductive wire arranged in the middle of the wire fixing ring can not be screwed up, the outer extending frame can extend outwards along the outer ring by the thrust generated by the boosting strip to the outer extending frame, therefore, the extended extending frame can clamp the conductive wire, and the problem that the wire fixing ring cannot adapt to the conductive wire with smaller diameter due to the fact that the diameter of the wire fixing ring is not variable is effectively avoided.

Description

Rotary type electroplating mechanical cantilever conductive mechanism

Technical Field

The invention relates to the field of electroplating, in particular to a cantilever conductive mechanism of a rotary electroplating machine.

Background

Based on the above description, the inventor finds that the conventional cantilever conductive mechanism of a rotary electroplating machine mainly has the following disadvantages, for example:

because the front end holding head of rotation electroplating machinery cantilever can rotate by a wide margin, and can drive the conductor wire rather than being connected when the holding head rotates and carry out synchronous rotation, if the holding head carries out 360 rotations, inside conductor wire also can corresponding follow the rotation by screwing up, and the conductor wire uses external insulation skin for a long time and high temperature softening can appear to the conductor wire to lead to the insulating skin of conductor wire outside can appear the damaged condition under screwing up repeatedly easily.

Disclosure of Invention

Aiming at the problems, the invention provides a cantilever conductive mechanism of a rotary electroplating machine.

In order to achieve the purpose, the invention is realized by the following technical scheme: a rotary type cantilever conductive mechanism of an electroplating machine structurally comprises a middle connecting rod, a connecting arm, a supporting rod, a base and a clamping mechanism, wherein the middle connecting rod is movably clamped with the connecting arm, the connecting arm is connected with the upper end of the supporting rod, the supporting rod is welded with the base, and the clamping mechanism is installed at the front end of the middle connecting rod; the clamping mechanism comprises an outer frame, a conductive mechanism, a clamping head and a rotating disc, the outer frame is connected with the rotating disc, the conductive mechanism is fixedly embedded at the upper end position of the rotating disc, and the clamping head is installed at the bottom position of the rotating disc.

As a further optimization of the invention, the conductive mechanism comprises a heat conducting rod, a heat dissipating plate, a rotating mechanism and conductive wires, the heat conducting rod is fixedly embedded in the side position of the conductive wires, the heat dissipating plate is hinged with the front end of the heat conducting rod, the conductive wires are connected with the rotating mechanism, four heat dissipating plates are arranged, and two heat dissipating plates are uniformly distributed symmetrically on the left side and the right side of the conductive wires through the matching of the heat conducting rods.

As a further optimization of the invention, the rotating mechanism comprises an outer disc, a stress block, an elastic sheet, an electrifying block, a wire fixing ring and an integration disc, wherein the stress block is movably clamped with the inner side of the outer disc, the elastic sheet is installed between the stress block and the electrifying block, the tail end of the electrifying block is electrically connected with the wire fixing ring, the electrifying block is fixedly connected with the integration disc in an embedded manner, the wire fixing ring and the integration disc are of an integrated structure, the stress block is provided with six, and the stress blocks are uniformly distributed on the inner side of the outer disc in a circular manner.

As a further optimization of the present invention, the force-bearing block includes a contact block, a frame, a bottom plate, a conductive rod, a linking frame, and a guide plate, the contact block is in clearance fit with the frame, the frame and the bottom plate are integrated, the conductive rod penetrates through the bottom plate, one end of the linking frame is movably engaged with the guide plate, the other end of the linking frame is fixedly connected with the conductive rod, the guide plate is installed at the bottom of the contact block, and the contact block can slide downward along the frame by the extrusion of the inner side of the object on the contact block.

As a further optimization of the invention, the wire fixing ring comprises a fixed block, a boosting strip, an outward extending frame and an outer ring, wherein the fixed block and the outer ring are of an integrated structure, the boosting strip is arranged between the fixed block and the outward extending frame, the outward extending frame is movably clamped at the inner positions of the fixed block and the outer ring, and six outward extending frames are uniformly distributed on the outer ring in a circular manner.

As a further optimization of the invention, the overhanging frame comprises a plate body, elastic sheets, an inner clamping block, a power transmission line and a linkage rod, wherein the elastic sheets are arranged between the plate body and the inner clamping block, the inner clamping block is movably clamped with the linkage rod, the power transmission line is fixed between the inner clamping block and the plate body, the linkage rod is hinged with the bottom of the plate body, and the two inner clamping blocks are uniformly and symmetrically distributed at the bottom of the plate body.

As a further optimization of the present invention, the inner clamping block includes a receiving plate, a resilient strip, an electricity guiding frame, and a plate surface, the resilient strip is mounted between the receiving plate and the plate surface, the electricity guiding frame penetrates through the inner position of the plate surface, and the plate surface can be contracted inwards by the extrusion of the object on the plate surface until the electricity guiding frame and the receiving plate are attached to each other.

The invention has the following beneficial effects:

1. drive the holding head through the rolling disc and rotate, can make the outer dish follow the rolling disc and rotate, and to the extrusion that the atress piece produced when just rotating through the outer dish, can make the inside shrink of atress piece to the rotation that makes the integration dish can't follow the outer dish rotates in step, so makes the conductor wire of solid ring mid-mounting of line can not rotate and screw up.

2. The thrust generated by the boosting strip to the external extension frame can enable the extension frame to extend outwards along the outer ring, so that the extended extension frame can clamp the conductive wire, and the problem that the wire fixing ring cannot adapt to the conductive wire with smaller diameter due to the fact that the diameter of the wire fixing ring is not changeable is effectively avoided.

Drawings

FIG. 1 is a schematic structural diagram of a cantilever conductive mechanism of a rotary electroplating machine according to the present invention.

FIG. 2 is a front half-sectional view of the clamping mechanism of the present invention.

Fig. 3 is a schematic structural view of a partial front cross section of the conductive mechanism of the present invention.

Fig. 4 is a schematic structural diagram of a top view section of the rotating mechanism of the present invention.

FIG. 5 is a schematic top view of the stress block of the present invention.

FIG. 6 is a schematic top view of a wire-bonded ring according to the present invention.

FIG. 7 is a top half-sectional schematic view of an outrigger frame of the present invention.

FIG. 8 is a top half-sectional structural view of the inner clamping block of the present invention.

In the figure: middle connecting rod-1, connecting arm-2, supporting rod-3, base-4, clamping mechanism-5, outer frame-51, conducting mechanism-52, clamping head-53, rotating disc-54, conducting rod-a 1, heat dissipation plate-a 2, rotating mechanism-a 3, conducting wire-a 4, outer disc-a 31, stress block-a 32, elastic sheet-a 33, energizing block-a 34, wire fixing ring-a 35, integration disc-a 36, contact block-b 1, frame-b 2, bottom plate-b 3, conducting rod-b 4, connecting frame-b 5, guide plate-b 6, fixing block-c 1, boosting strip-c 2, outward extending frame-c 3, outer ring-c 4, plate-c 31, elastic sheet-c 32, inner clamping block-c 33, inner clamping block-c 34, Linkage rod-c 35, bearing plate-d 1, rebound strip-d 2, electricity leading frame-d 3 and plate surface-d 4.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1

As shown in fig. 1-5:

the invention provides a rotary type cantilever conductive mechanism of an electroplating machine, which structurally comprises a middle connecting rod 1, a connecting arm 2, a supporting rod 3, a base 4 and a clamping mechanism 5, wherein the middle connecting rod 1 is movably clamped with the connecting arm 2, the connecting arm 2 is connected with the upper end of the supporting rod 3, the supporting rod 3 is welded with the base 4, and the clamping mechanism 5 is arranged at the front end position of the middle connecting rod 1; the clamping mechanism 5 comprises an outer frame 51, a conductive mechanism 52, a clamping head 53 and a rotating disc 54, wherein the outer frame 51 is connected with the rotating disc 54, the conductive mechanism 52 is embedded in the upper end position of the rotating disc 54, and the clamping head 53 is installed at the bottom position of the rotating disc 54.

The conductive mechanism 52 comprises a heat conducting rod a1, a heat dissipation plate a2, a rotating mechanism a3 and a conductive wire a4, the heat conducting rod a1 is embedded in the side position of the conductive wire a4, the heat dissipation plate a2 is hinged to the front end of the heat conducting rod a1, the conductive wire a4 is connected with the rotating mechanism a3, four heat dissipation plates a2 are arranged, the two heat dissipation plates are symmetrically distributed on the left side and the right side of the conductive wire a4 through the matching of the heat conducting rod a1, and the heat dissipation plates a2 can repeatedly swing up and down along the heat conducting rod a1 through vibration generated by mechanism rotation, so that the heat dissipation plates a2 can dissipate heat generated by the conductive wire a 4.

The rotating mechanism a3 comprises an outer disc a31, a force-bearing block a32, an elastic sheet a33, a current-carrying block a34, a wire-fixing ring a35 and an integration disc a36, wherein the force-bearing block a32 is movably clamped with the inner side of the outer disc a31, the elastic sheet a33 is installed between the force-bearing block a32 and the current-carrying block a34, the tail end of the current-carrying block a34 is electrically connected with the wire-fixing ring a35, the current-carrying block a34 is fixedly embedded with the integration disc a36, the wire-fixing ring a35 and the integration disc a36 are of an integrated structure, the force-bearing blocks a32 are provided with six and uniformly distributed in a circular shape on the inner side of the outer disc a31, the force-bearing blocks a32 can be contracted inwards through the rotation of the outer disc a31, and the outer disc a31 cannot drive the integration disc a36 to rotate.

The stress block a32 comprises a contact block b1, a frame b2, a bottom plate b3, a bottom plate b3, a conductive rod b4, an engagement frame b5 and a guide plate b6, the contact block b1 is in clearance fit with the frame b2, the frame b2 and the bottom plate b3 are of an integrated structure, the conductive rod b4 penetrates through the inner position of the bottom plate b3, one end of the engagement frame b5 is movably clamped with the guide plate b6, the other end of the engagement frame b5 is fixedly connected with the conductive rod b4, the guide plate b6 is mounted at the bottom position of the contact block b1, the contact block b1 can slide downwards along the frame b2 through the pressing of the inner side of an object on the contact block b1, and the contact block b1 can be always attached to the inner side of the object.

The detailed use method and action of the embodiment are as follows:

in the invention, as the clamping head 53 on the clamping mechanism 5 can rotate greatly, and the conducting wire connected with the clamping head 53 can be driven to rotate synchronously when the clamping head 53 rotates, if the clamping head 53 rotates for 360 degrees, the internal conducting wire can correspondingly rotate and be screwed down, and the conducting wire is used for a long time, the external insulating skin can be softened at high temperature, so that the insulating skin outside the conducting wire can be damaged under the condition of repeated screwing, the problems can be effectively solved through the heat dissipation plate a2 on the conducting mechanism 52 and the rotating mechanism a3, the heat dissipation plate a2 can repeatedly swing along the conducting rod a1 through the vibration generated by the rotation of the clamping head 53, so that the air flow generated by the swinging of the heat dissipation plate a2 can dissipate the heat generated on the conducting wire a4, and the condition that the insulating skin outside the conducting wire a4 is softened due to overhigh temperature on the conducting wire a4 is effectively avoided, the clamping head 53 is driven to rotate by the rotating disc 54, the outer disc a31 can rotate along with the rotating disc 54, the stress block a32 can contract inwards by the extrusion of the stress block a32 when the outer disc a31 rotates, so that the integrated disc a36 cannot rotate synchronously along with the rotation of the outer disc a31, the conducting wire arranged in the middle of the wire fixing ring a35 cannot rotate and be screwed, the stress block a32 can compress the contact block b1 by the inner side of the outer disc a31 when contracting, the contact block b1 can be always attached to the inner side of the stress block 63a 32, the current transmitted by the conducting wire arranged in the middle of the linkage rod c35 can be continuously transmitted to the outer disc a31, and the outer disc a31 can transmit the current to the clamping head 53 of the rotating disc 54, so that the normal operation of the clamping head 53 can be ensured, and the clamping head 53 can be effectively prevented from rotating 360 degrees, the internal conductive wire is correspondingly screwed down along with the rotation.

Example 2

As shown in fig. 6-8:

the wire fixing ring a35 comprises a fixing block c1, a boosting bar c2, an outward extending frame c3 and an outer ring c4, the fixing block c1 and the outer ring c4 are of an integrated structure, the boosting bar c2 is installed between the fixing block c1 and the outward extending frame c3, the outward extending frame c3 is movably clamped at the inner positions of the fixing block c1 and the outer ring c4, the outward extending frame c3 is provided with six pieces, the six pieces are uniformly distributed on the outer ring c4 in a circular shape, and the outward extending frame c3 can fix the position of the conductive wire by thrust generated to the outward extending frame c3 through the boosting bar c 2.

The overhanging frame c3 comprises a plate body c31, an elastic sheet c32, an inner clamping block c33, a power transmission line c34 and a linkage rod c35, wherein the elastic sheet c32 is installed between the plate body c31 and the inner clamping block c33, the inner clamping block c33 is movably clamped with the linkage rod c35, the power transmission line c34 is fixed between the inner clamping block c33 and the plate body c31, the linkage rod c35 is hinged to the bottom of the plate body c31, the inner clamping blocks c33 are provided with two parts, the two parts are uniformly distributed at the bottom of the plate body c31 symmetrically, and an inner core of an electric wire can be clamped through the two inner clamping blocks c 33.

The inner clamping block c33 comprises a bearing plate d1, a rebound strip d2, an electricity leading frame d3 and a plate d4, wherein the rebound strip d2 is installed between the bearing plate d1 and the plate d4, the electricity leading frame d3 penetrates through the inner position of the plate d4, the plate d4 can be contracted inwards by squeezing the plate d4 through an object until the electricity leading frame d3 is attached to the bearing plate d1, and the plate d4 which loses squeezing can be rapidly pushed to be separated from the bearing plate d1 through the rebound strip d 2.

The detailed use method and action of the embodiment are as follows:

in the invention, because the specifications of the electric wires are various, and the diameter of the wire fixing ring a35 is fixed, so that the wire fixing ring a35 cannot be fixedly connected with the conductive wire with a smaller diameter, such problems can be effectively solved by the outward extending frame c3 on the wire fixing ring a35, the outward extending frame c3 can be extended outwards along the outer ring c4 by the thrust generated by the boosting strip c2 on the outward extending frame c3 until the front end of the outward extending frame c3 is attached to the outer surface of the electric wire, so that the extended outward extending frame c3 can fix the position of the conductive wire, and the inner wire core can extrude between the two inner clamping blocks c33, so that the inner clamping block c33 clamps the inner wire core under the matching of the elastic sheet c32 and the linkage rod c35, and the current in the electric wire can be led into the outer ring c4 through the transmission line c34, thereby effectively avoiding that the diameter of the wire fixing ring a35 cannot be changed, so that the diameter of the wire fixing ring a35 cannot be adapted to the conductive wire with a smaller diameter, and the elastic strip d2 can push the plate d4 which loses the extrusion of the electric lead to be separated from the bearing plate d1, so that the electric lead frame d3 can be quickly separated from the bearing plate d1, the wire fixing ring a35 can be powered off immediately when the electric lead is removed from the wire fixing ring a35, and the situation that a small part of current still exists on the wire fixing ring a35 when the electric lead is removed from the wire fixing ring a35 due to overlarge current is effectively avoided.

The technical solutions of the present invention or similar technical solutions designed by those skilled in the art based on the teachings of the technical solutions of the present invention are all within the scope of the present invention to achieve the above technical effects.

Claims (7)

1. The utility model provides a rotation electroplating machinery cantilever electrically conductive mechanism, its structure includes well extension rod (1), links up arm (2), bracing piece (3), base (4), fixture (5), well extension rod (1) and link up arm (2) activity block, link up arm (2) and be connected with the upper end of bracing piece (3), bracing piece (3) and base (4) weld mutually, its characterized in that: the clamping mechanism (5) is arranged at the front end of the middle connecting rod (1);

the clamping mechanism (5) comprises an outer frame (51), a conductive mechanism (52), a clamping head (53) and a rotating disc (54), the outer frame (51) is connected with the rotating disc (54), the conductive mechanism (52) is embedded and fixed at the upper end position of the rotating disc (54), and the clamping head (53) is installed at the bottom position of the rotating disc (54).

2. The cantilever electric mechanism of a rotary electroplating machine as claimed in claim 1, wherein: the conductive mechanism (52) comprises a heat conduction rod (a1), a heat dissipation plate (a2), a rotating mechanism (a3) and a conductive wire (a4), the heat conduction rod (a1) is embedded in the side position of the conductive wire (a4), the heat dissipation plate (a2) is hinged with the front end of the heat conduction rod (a1), and the conductive wire (a4) is connected with the rotating mechanism (a 3).

3. The cantilever electric mechanism of a rotary electroplating machine as claimed in claim 2, wherein: the rotating mechanism (a3) comprises an outer disc (a31), a stress block (a32), an elastic sheet (a33), a power-on block (a34), a wire fixing ring (a35) and an integration disc (a36), wherein the stress block (a32) is movably clamped with the inner side of the outer disc (a31), the elastic sheet (a33) is installed between the stress block (a32) and the power-on block (a34), the tail end of the power-on block (a34) is electrically connected with the wire fixing ring (a35), the power-on block (a34) is fixedly connected with the integration disc (a36), and the wire fixing ring (a35) and the integration disc (a36) are of an integrated structure.

4. The cantilever electric mechanism of a rotary electroplating machine as claimed in claim 3, wherein: the stress block (a32) comprises a contact block (b1), a frame body (b2), a bottom plate (b3), a bottom plate (b3), a conductive rod (b4), a connecting frame (b5) and a guide plate (b6), the contact block (b1) is in clearance fit with the frame body (b2), the frame body (b2) and the bottom plate (b3) are of an integrated structure, the conductive rod (b4) penetrates through the inner position of the bottom plate (b3), one end of the connecting frame (b5) is movably clamped with the guide plate (b6), the other end of the connecting frame (b5) is fixedly connected with the conductive rod (b4), and the guide plate (b6) is mounted at the bottom position of the contact block (b 1).

5. The cantilever electric mechanism of a rotary electroplating machine as claimed in claim 3, wherein: the wire fixing ring (a35) comprises a fixing block (c1), a boosting strip (c2), an outward extending frame (c3) and an outer ring (c4), the fixing block (c1) and the outer ring (c4) are of an integrated structure, the boosting strip (c2) is installed between the fixing block (c1) and the outward extending frame (c3), and the outward extending frame (c3) is movably clamped at the inner positions of the fixing block (c1) and the outer ring (c 4).

6. The cantilever electric mechanism of a rotary electroplating machine as claimed in claim 5, wherein: the outward extending frame (c3) comprises a plate body (c31), elastic pieces (c32), an inner clamping block (c33), a power transmission line (c34) and a linkage rod (c35), wherein the elastic pieces (c32) are installed between the plate body (c31) and the inner clamping block (c33), the inner clamping block (c33) is movably clamped with the linkage rod (c35), the power transmission line (c34) is fixed between the inner clamping block (c33) and the plate body (c31), and the linkage rod (c35) is hinged to the bottom of the plate body (c 31).

7. The cantilever conducting mechanism of a rotary electroplating machine as claimed in claim 6, wherein: the inner clamping block (c33) comprises a bearing plate (d1), a rebound strip (d2), an electricity leading frame (d3) and a plate surface (d4), wherein the rebound strip (d2) is installed between the bearing plate (d1) and the plate surface (d4), and the electricity leading frame (d3) penetrates through the inner position of the plate surface (d 4).

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