CN114985199B - Gluing device for producing high-voltage ultrafast recovery diode - Google Patents

Abstract

The invention discloses a gluing device for producing a high-voltage ultrafast recovery diode, wherein a machine table is connected with a diode mounting part in a sliding manner through guide cavities on two sides, a plurality of clamping parts which rotate synchronously are arranged on the diode mounting part and are used for clamping the diode, a gluing part for gluing the diode is erected at one end of a table top of the machine table, a drying part for drying the diode after gluing is erected at the other end of the table top of the machine table, the diode mounting part can be switched between the gluing part and the drying part in a sliding manner, so that when the diode enters the gluing part and the drying part along with the diode mounting part, the diode can realize rotary gluing and rotary drying, rotary gluing can enable the gluing on the peripheral surface of the diode to be more uniform, the gluing quality of the diode is improved, rotary drying can enable the glued diode to be uniformly heated, the drying quality of the surface of the diode is improved, and the gluing quality of the diode is effectively improved.

Description

Gluing device for producing high-voltage ultrafast recovery diode

Technical Field

The invention relates to the technical field of diode production, in particular to a gluing device for producing a high-voltage ultrafast recovery diode.

Background

One of the diode and electronic element has two electrodes, which only allows current to flow in a single direction, many of them are used for their rectifying function, while the varactor is used as an electronic adjustable capacitor, and the most common function of the diode is to allow current to flow in a single direction (called forward bias) and to block current in the reverse direction (called reverse bias), so the diode can be thought of as an electronic check valve.

As patent application number 2018221881563 discloses a rubber coating device is used in production of super fast recovery diode of high pressure, including stage body, stoving case, fixed subassembly and storage glue case, the inside roll table of having laid of stage body, and the roll table upper end is improved level and has been seted up the second spout on the both sides inner wall of stage body, be provided with fixed subassembly on the roll table, fixed subassembly includes the shell of cuboid form and the multiunit through-hole of seting up on the shell lateral wall, the multiunit has been seted up side by side to the through-hole, the multiunit the through-hole is the distribution of staggering, the intubate is installed in the inside rotation of through-hole, the other end fixedly connected with pulley of through-hole is kept away from to the intubate, the pulley stretches into to the inside sliding connection with it of second spout, the inside grafting of intubate has the diode, the symmetry is installed two sets of stands on the outer wall of stage body both sides, and threaded connection has storage glue case between the stand.

The scheme has the following defects in the using process, the gluing of a single diode in the scheme needs two times of clamping, namely, the processing efficiency of the diode is reduced, and the two ends of the single diode are respectively glued and dried, so that the coating amount and the drying degree of the two ends of the diode are different easily, and the normal use of the diode is influenced.

Disclosure of Invention

The invention aims to provide a gluing device for producing a high-voltage ultrafast recovery diode, wherein a machine table is connected with a diode mounting part in a sliding manner through guide cavities on two sides, a plurality of clamping parts which rotate synchronously are arranged on the diode mounting part and are used for clamping the diode, a gluing part for gluing the diode is erected at one end of a table top of the machine table, a drying part for drying the diode after gluing is erected at the other end of the table top of the machine table, the diode mounting part can be switched between the gluing part and the drying part in a sliding manner, rotary gluing and rotary drying of the diode are realized, and the coating amount and the drying degree of the same diode are effectively ensured to be the same.

The purpose of the invention can be realized by the following technical scheme:

a gluing device for producing a high-voltage ultrafast recovery diode comprises a machine table, wherein the machine table is connected with a diode mounting part in a sliding manner through guide cavities on two sides;

the diode mounting part is provided with a plurality of clamping parts which rotate synchronously, and the clamping parts are used for clamping diodes;

wherein, a gluing part for gluing the diode is erected at one end of the table top of the machine table;

a drying part for drying the diode after gluing is erected at the other end of the table top of the machine table;

the diode mounting part is switched between the gluing part and the drying part in a sliding mode.

As a further scheme of the invention: the diode mounting part is integrally of a cavity structure with a U-shaped structure;

wherein, the vertical both sides of cavity structure form the rectangle cavity, vertically are provided with the pivot in the cavity of diode installation department inside along vertically, and the both ends of pivot just are located the inside bonding of rectangle cavity and have the action wheel, the rectangle cavity of diode installation department both sides is inside to be provided with a plurality of double-deck gears along the horizontal direction, and wherein the pinion of arbitrary one double-deck gear is connected with the action wheel meshing, passes through the gear belt to the gear wheel of a plurality of double-deck gears and connects.

As a further scheme of the invention: the double-layer gear is bonded on the transmission shaft, and one end of the transmission shaft penetrates through the side wall of the rectangular cavity and is connected with a clamping part for mounting the diode.

As a further scheme of the invention: the clamping part is of a cylindrical structure with two uncovered ends.

As a further scheme of the invention: an internal thread is formed at one end of the cylindrical structure of the clamping part, the transmission shaft is in threaded connection with the clamping part, a threaded hole is formed in the outer circumferential surface of the clamping part, which is close to one end of the transmission shaft, a locking screw is arranged in the threaded hole, and the tail end of the locking screw abuts against the transmission shaft.

As a further scheme of the invention: the inside bilateral symmetry of tubular structure of clamping portion is provided with the arc splint that are used for the diode to fix, two the arc splint are V type structure, and the big one end in opening of V type structure inserts the end for the diode.

As a further scheme of the invention: the back of the two arc-shaped clamping plates is fixedly provided with a guide rod, the guide rod is inserted into the guide column on the outer peripheral surface of the clamping part in a sliding mode, the guide rod is sleeved with a spring, one end of the spring is fixed to the arc-shaped clamping plates, and the other end of the spring is fixed to the inner wall of the clamping part.

As a further scheme of the invention: the guide cavity comprises lead screws horizontally arranged on two sides of the machine table, a screw seat is in threaded connection with each lead screw, guide blocks are vertically arranged on the inner side surfaces of the screw seats, and the tops of the guide blocks in the guide cavities on the two sides of the machine table are fixedly connected with the two longitudinal sides of the bottom of the diode mounting part.

As a further scheme of the invention: and a plurality of gluing pipes for coating are arranged in the gluing part.

As a further scheme of the invention: and a plurality of heating pipes for drying are arranged in the drying part.

The invention has the beneficial effects that:

(1) According to the invention, through the arrangement of the diode mounting part, when the diode enters the gluing part and the drying part along with the diode mounting part, the diode can realize rotary gluing and rotary drying, the rotary gluing can make the gluing on the peripheral surface of the diode more uniform, the gluing quality of the diode is improved, the rotary drying can make the diode after gluing uniformly heated, and the drying quality of the surface of the diode is improved, so that the gluing quality of the diode is effectively improved, namely, the coating amount and the drying degree of the same diode are effectively ensured to be the same;

(2) According to the invention, the diode mounting part is provided with the plurality of clamping parts, so that the diode mounting part can realize gluing and drying of a plurality of diodes at a time, and the gluing efficiency of the diodes is improved;

(3) According to the invention, the V-shaped structure is formed by the two arc-shaped clamping plates in the clamping part, and the end with the large opening of the V-shaped mechanism is the diode insertion end, namely the arc-shaped clamping plates on two sides are extruded in the insertion process of the diode, so that the arc-shaped clamping plates extrude the spring, and the arc-shaped clamping plates clamp the diode under the action of the elastic force of the spring, so that the diode is more conveniently and quickly disassembled and assembled on the clamping part.

Drawings

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

FIG. 1 is a front view of the present invention;

FIG. 2 is a schematic view of the structure of the guide chamber of the present invention;

FIG. 3 is a top view of the diode mounting section of the present invention;

FIG. 4 is a schematic view of the structure inside the diode mounting portion of the present invention;

FIG. 5 is a schematic view of the structure of the clamping portion of the present invention;

FIG. 6 is a schematic view of the structure of the hose of the present invention.

In the figure: 1. a machine platform; 101. a screw rod; 102. a nut seat; 103. a guide block;

2. a diode mounting section; 201. a rotating shaft; 202. a driving wheel; 203. a pinion gear; 204. a bull gear; 205. a gear belt; 206. a drive shaft; 207. a clamping part; 208. a guide post; 209. a guide bar; 210. a spring; 211. an arc-shaped splint;

3. a gluing part; 301. coating a rubber tube; 302. a fastening block; 303. adjusting the handle; 304. a connecting portion; 305. an L-shaped conveying bent pipe; 306. a main feed delivery conduit; 307. a control valve;

4. a drying section; 401. heating the tube.

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.

Referring to fig. 1-6, the present invention is a glue spreading device for producing a high-voltage ultrafast recovery diode, wherein a glue spreading portion 3 is disposed at one end of a table top of a machine table 1, the glue spreading portion 3 is used for spreading a glue on a diode, a drying portion 4 is disposed at the other end of the table top of the machine table 1, and the drying portion 4 is used for drying the glued diode;

the diode mounting part 2 is mounted on the table top of the machine table 1, the diode mounting part 2 is used for mounting and positioning a diode to be coated, and meanwhile, the diode is switched between the coating part 3 and the drying part 4 through the diode mounting part 2;

referring to fig. 2, guide cavities are respectively arranged on two longitudinal sides of the machine table 1, the guide cavities on the two sides have completely identical structures and move synchronously, wherein each guide cavity comprises a lead screw 101 horizontally arranged on the two sides of the machine table 1, a screw seat 102 is connected to the lead screw 101 in a threaded manner, a guide block 103 is vertically arranged on the inner side surface of the screw seat 102, and the tops of the guide blocks 103 in the guide cavities on the two sides of the machine table 1 are fixedly connected with two longitudinal sides of the bottom of the diode mounting part 2;

when the diode mounting part 2 moves, the screw rod 101 drives the screw base 102 to move in the horizontal direction under the driving of the motor at one end of the screw rod 101, the screw base 102 drives the guide block 103 to move in the horizontal direction, and the guide block 103 drives the diode mounting part 2 to reciprocate in the horizontal direction through the forward direction or the direction rotation of the motor, so that the switching of the gluing part 3 and the drying part 4 of the diode mounting part 2 on the machine table 1 is completed;

wherein, the side of the guide block 103 is against the side of the machine table 1.

Referring to fig. 3 and 4, the diode mounting part 2 is integrally of a U-shaped cavity structure, a rotating shaft 201 is disposed inside the cavity of the diode mounting part 2, and one end of the rotating shaft 201 penetrates through the diode mounting part 2 and is connected with a motor in front and is disposed along a direction perpendicular to the moving direction of the diode mounting part 2;

referring to fig. 4, the front side and the rear side of the cavity of the diode mounting portion 2 are rectangular cavities, driving wheels 202 are bonded to two ends of a rotating shaft 201 and located inside the rectangular cavities, a plurality of double-layer gears are arranged inside the rectangular cavities on the front side and the rear side of the diode mounting portion 2 along the horizontal direction, the double-layer gears are bonded to a transmission shaft 206 inside the rectangular cavities, one end of the transmission shaft 206 penetrates through the side surface of the rectangular cavity and is connected with a clamping portion 207, and the clamping portion 207 is used for limiting and mounting of a diode on the diode mounting portion 2;

in the rectangular cavity, a small gear 203 of any one double-layer gear is meshed with a driving wheel 202, and large gears 204 of a plurality of double-layer gears are connected through a gear belt 205;

when the synchronous transmission device is used, the motor drives the rotating shaft 201 to rotate, so that the driving wheels 202 at two ends of the rotating shaft 201 are in meshing transmission with the pinions 203 of the multiple layers of gears, the pinions 203 drive the large gears 204 to drive the gear belts 205 to move, synchronous rotation of the multiple double-layer gears is realized, and the transmission shafts 206 connected with the double-layer gears drive the clamping parts 207 to rotate;

when the clamping part 207 clamps the diode and the diode enters the gluing part 3, the diode is rotationally glued through the rotation of the clamping part 207, so that the whole peripheral surface of the diode is uniformly glued, and the gluing quality of the diode is improved;

the clamping part 207 is a cylindrical sleeve, guide posts 208 are symmetrically arranged on two sides of the outer peripheral surface of the cylindrical sleeve, arc-shaped clamping plates 211 are symmetrically arranged on two sides in the cylindrical sleeve, the two arc-shaped clamping plates 211 are of a V-shaped structure, and the end with the large opening of the V-shaped structure is a diode insertion end;

the back surfaces of the two arc-shaped clamping plates 211 are fixedly provided with guide rods 209, the guide rods 209 are inserted in the guide columns 208 of the cylindrical sleeve in a sliding mode, the guide rods 209 are sleeved with springs 210, one ends of the springs 210 are fixed on the arc-shaped clamping plates 211, and the other ends of the springs 210 are fixed on the inner wall of the cylindrical sleeve;

when the clamping device is used, one end of the diode is inserted into the clamping part 207, one end of the diode is inserted along the end with the large opening of the V-shaped structure, the arc-shaped clamping plates 211 on the two sides are extruded, the arc-shaped clamping plates 211 extrude the spring 210, and the arc-shaped clamping plates 211 clamp the diode under the action of the elastic force of the spring 210;

referring to fig. 3, the clamping portion 207 is connected to the rotating shaft 201 through a screw thread, that is, the cylindrical sleeve is connected to the external screw thread at the end of the rotating shaft 201 through an internal screw thread, and a threaded hole is formed in the outer circumferential surface of the cylindrical sleeve, and a locking screw is disposed in the threaded hole and abuts against the end of the rotating shaft 201 and the surface of the outer circumferential surface.

Referring to fig. 1 and 6, a plurality of glue applying pipes 301 are arranged in parallel in the horizontal direction inside the glue applying part 3, one end of each glue applying pipe 301 is rotatably connected in a connecting part 304, the connecting part 304 is fixedly connected with one end of an L-shaped conveying elbow 305, the other end of the L-shaped conveying elbow 305 penetrates through a protective box cover of the diode mounting part 2 and is externally connected with a main conveying pipeline 306, and the main conveying pipeline 306 is externally connected with a glue applying solution box;

a control valve 307 is arranged on a pipeline of the L-shaped conveying elbow 305 penetrating through one end of the protective box cover, and the opening and closing of the rubber coating pipe 301 are realized through the control valve 307;

the bottom of the outer circumferential surface of the glue coating pipe 301 can be connected with a plurality of glue spraying heads for spraying diodes;

an adjusting handle 303 is arranged at one end of the glue coating pipe 301 penetrating through the front face of the protective box cover, and the adjustment of the glue coating angle of the glue coating pipe 301 is realized by rotating the adjusting handle 303, wherein a fastening block 302 is arranged on the outer peripheral surface of the glue coating pipe 301 positioned outside the protective box cover, and a locking screw is arranged on the fastening block 302 and used for fixing the glue coating pipe 301 on the protective box cover;

the protective box cover is of a transparent structure, so that workers can check the gluing condition of the diode in the gluing part 3 in real time;

referring to fig. 1, a plurality of heating pipes 401 are arranged in parallel inside the drying part 4, and the heating pipes 401 are used for drying the diode after glue is applied;

wherein, the heating pipe 401 inside the drying part 4 can be replaced by an air heater or other heating equipment as long as the drying of the glue coating diode can be realized.

Referring to fig. 1, the gluing part 3 and the drying part 4 have basically the same inner size for the sliding of the diode mounting part 2, so that the diode mounting part 2 can be switched between the gluing part 3 and the drying part 4;

wherein, the guide chamber both ends of board 1 both sides are located gluing portion 3 and stoving portion 4 inside respectively.

The application method of the gluing device for producing the high-voltage ultrafast recovery diode comprises the following steps:

s1: inserting one end of a diode to be glued into the V-shaped structure of the two arc-shaped clamping plates 211, extruding the arc-shaped clamping plates 211 on the two sides in the process of inserting the diode, extruding the spring 210 by the arc-shaped clamping plates 211, clamping the diode by the arc-shaped clamping plates 211 under the action of the elastic force of the spring 210, and finishing the fixed installation of the diode on the clamping part 207;

s2: through the driving action of the guide cavities at the two sides of the machine table 1, namely, the motor drives the screw rod 101 to rotate, the screw rods 101 at the two sides of the machine table 1 drive the screw seat 102 to move in the horizontal direction, namely, the screw seat 102 drives the guide block 103 to move in the horizontal direction, and through the forward rotation of the motor, the guide block 103 drives the diode mounting part 2 to enter the gluing part 3;

s3: the diode mounting part 2 enters the gluing part 3, the rotating shaft 201 is driven to rotate by a motor, driving wheels 202 at two ends of the rotating shaft 201 are in meshing transmission with pinions 203 of the multiple layers of gears, the pinions 203 drive large gears 204 to drive gear belts 205 to move, synchronous rotation of the multiple double-layer gears is achieved, then a transmission shaft 206 connected with the double-layer gears drives a clamping part 207 to rotate, and synchronous rotation of all diodes on the diode mounting part 2 is achieved;

s4: in the rotation process of the diode, a control valve 307 is opened, so that a glue coating solution enters the glue coating tube 301 through a main material conveying pipeline 306, and the rotating diode is sprayed through a plurality of glue spraying heads on the glue coating tube 301, so that the rotating glue coating of the diode in the glue coating part 3 is realized;

s5: after the diode is coated with glue in the gluing part 3, the screw rod 101 is driven to rotate in the reverse direction by the motor, so that the screw rods 101 on the two sides of the machine table 1 drive the screw seat 102 to move in the horizontal direction, namely the screw seat 102 drives the guide block 103 to drive the diode mounting part 2 to enter the drying part 4, and the diode after being coated with glue is dried by the heating pipe 401 in the drying part 4.

In the S5, during the gluing and drying process of the drying part 4 on the diodes, the working process of the diode mounting part 2 is consistent with the process in the gluing part 3, the motor drives the rotating shaft 201 to rotate, so that the driving wheels 202 at two ends of the rotating shaft 201 are in meshing transmission with the pinions 203 of the multiple layers of gears, the pinions 203 drive the large gears 204 to drive the gear belts 205 to move, thereby realizing synchronous rotation of the multiple layers of gears, the transmission shafts 206 connected with the double layers of gears drive the clamping parts 207 to rotate, realizing synchronous rotation of all the diodes on the diode mounting part 2, realizing rotary drying of the diodes in the drying part 4, and improving the drying quality of the diodes.

Although one embodiment of the present invention has been described in detail, the description is only for the purpose of illustrating the preferred embodiments of the present invention and should not be taken as limiting the scope of the invention. All equivalent changes and modifications made within the scope of the present invention shall fall within the scope of the present invention.

Claims (8)

1. A gluing device for producing a high-voltage ultrafast recovery diode comprises a machine table (1) and is characterized in that the machine table (1) is connected with a diode mounting part (2) through guide cavities on two sides in a sliding mode;

a plurality of clamping parts (207) which rotate synchronously are arranged on the diode mounting part (2), and the clamping parts (207) are used for clamping the diode;

wherein, a gluing part (3) for gluing the diode is erected at one end of the table top of the machine table (1);

a drying part (4) for drying the diode after gluing is erected at the other end of the table top of the machine table (1);

the diode mounting part (2) is switched between the gluing part (3) and the drying part (4) in a sliding manner;

the diode mounting part (2) is integrally of a cavity structure with a U-shaped structure;

the LED lamp comprises a cavity structure, a rotating shaft (201) is longitudinally arranged in the cavity of a diode mounting part (2), driving wheels (202) are bonded at two ends of the rotating shaft (201) and positioned in the rectangular cavity, a plurality of double-layer gears are arranged in the rectangular cavity at two sides of the diode mounting part (2) along the horizontal direction, a small gear (203) of any one double-layer gear is meshed with the driving wheels (202), and large gears (204) of the double-layer gears are connected through gear belts (205);

the double-layer gear is bonded on the transmission shaft (206), and one end of the transmission shaft (206) penetrates through the side wall of the rectangular cavity and is connected with a clamping part (207) for mounting the diode.

2. The gluing device for producing the high-voltage ultrafast recovery diode as claimed in claim 1, wherein the clamping part (207) is a cylindrical structure with two uncovered ends.

3. The gluing device for producing the high-voltage ultrafast recovery diode as claimed in claim 2, wherein one end of the cylindrical structure of the clamping portion (207) is provided with an internal thread, the transmission shaft (206) is in threaded connection with the clamping portion (207), the outer circumferential surface of the clamping portion (207) near one end of the transmission shaft (206) is provided with a threaded hole, a locking screw is arranged in the threaded hole, and the tail end of the locking screw abuts against the transmission shaft (206).

4. The gluing device for producing the high-voltage ultrafast recovery diode as claimed in claim 2, wherein arc-shaped clamping plates (211) for fixing the diode are symmetrically arranged on two sides inside the cylindrical structure of the clamping part (207), the two arc-shaped clamping plates (211) are in a V-shaped structure, and the diode insertion end is the end with the larger opening of the V-shaped structure.

5. The gluing device for the production of the high-voltage ultrafast recovery diode as claimed in claim 4, wherein guide rods (209) are fixedly arranged on the back surfaces of the two arc-shaped clamping plates (211), the guide rods (209) are slidably inserted into guide posts (208) on the outer circumferential surface of the clamping portion (207), springs (210) are sleeved on the guide rods (209), one ends of the springs (210) are fixed on the arc-shaped clamping plates (211), and the other ends of the springs (210) are fixed on the inner wall of the clamping portion (207).

6. The gluing device for the production of the high-voltage ultrafast recovery diode according to claim 1, wherein the guide cavity comprises lead screws (101) horizontally arranged at two sides of the machine table (1), a screw seat (102) is in threaded connection with the lead screws (101), guide blocks (103) are vertically arranged on the inner side surface of the screw seat (102), and the tops of the guide blocks (103) in the guide cavities at two sides of the machine table (1) are fixedly connected with the longitudinal two sides of the bottom of the diode mounting part (2).

7. The gluing device for the production of high-voltage ultrafast recovery diodes as claimed in claim 1, wherein a plurality of gluing pipes (301) for coating are arranged in said gluing portion (3).

8. The gluing device for the production of high-voltage ultrafast recovery diodes according to claim 1, wherein a plurality of heating pipes (401) for drying are arranged in the drying part (4).

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