CN213824371U - Production system of damping cloth polishing pad - Google Patents

Abstract

The utility model discloses a production system of a damping cloth polishing pad, which comprises a raw material mixing device, a forming machine and a conveying device; the tail end of the conveying device is provided with a cutting machine, and the discharge end of the cutting machine is provided with a collecting and charging plate; the raw material mixing device comprises a fixed shell and a stirring part; the bottom of the fixed shell is connected with a forming machine through a discharge pipeline; the stirring part comprises a stirring rotating shaft, a stirring rotary rod and an annular stirring blade; the stirring rotating shaft comprises an upper stirring rotating shaft and a lower stirring rotating shaft which are connected through a coupler, and the stirring rotating rod is fixedly connected with the annular stirring blade through an embedding device; the transportation device comprises a transportation part and a curing part; the conveying part comprises a first conveyor belt and a second conveyor belt; the curing part comprises a heating resistor block and a cooling wind tunnel; the first conveyor belt and the second conveyor belt are respectively provided with a bearing and conveying device; therefore, the device is utilized to realize the purposes of uniform mixing and low energy consumption.

Description

Production system of damping cloth polishing pad

Technical Field

The utility model relates to a production preparation field of damping cloth polishing pad specifically is a production system of damping cloth polishing pad.

Background

The polishing pad is a polyurethane polishing material with a large number of micropores on the surface, and is also called polyurethane damping cloth. The polyurethane provides excellent flexibility, elasticity and wear resistance, and the micropores are good storage places of the polishing solution, so that the damping cloth has a very good polishing effect and is usually used in fields with very high requirements on polishing quality, such as optical crystals, optical glass, sapphire, MPO optical fiber connectors, semiconductor silicon wafers, metallographic analysis and the like.

Among the production flow of present damping cloth polishing pad, the raw materials that will polish the pad adopt stirring pivot formula or the mixer of pump blade formula to carry out simple stirring in earlier stage and mix mostly, consequently to the polishing pad of different proportion formulas, adopt the mixer of different rotational speeds or different stirring leaves mostly, with guaranteeing the stirring, consequently, the production system of general polishing pad occupies an area of comparatively huge mostly, and adopt the mixed stirring of single direction, very easily produce the inhomogeneous condition of stirring, thereby lead to the emergence of waste product.

And because the polishing pad is formed in the existing stage, most of the polishing pads need to enter a curing machine for curing, so that material loss in a certain curing stage exists, waste products are not easy to sort out when the materials which are not uniformly mixed are stirred for curing after forming, the waste products are timely stopped from being damaged, and the waste products increase energy consumption, so that the production system of the damping cloth polishing pad with uniform material mixing and low energy consumption is continued at present.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome prior art's not enough, provide a production system of damping cloth polishing pad of compounding even, low energy consumption.

The purpose of the utility model is realized through the following technical scheme:

a production system of a damping cloth polishing pad comprises a raw material mixing device and a forming machine arranged on one side of the raw material mixing device; a conveying device is arranged below the forming machine; the tail end of the conveying device is provided with a cutting machine; the discharge end of the cutting machine is provided with a collecting and charging plate;

the raw material mixing device comprises a fixed shell and a stirring part fixed in the fixed shell; the bottom of the fixed shell is connected with the feeding end of the forming machine through a discharging pipeline; the stirring part comprises a stirring rotating shaft, a stirring rotary rod and an annular stirring blade; the side surfaces of the rotary stirring rotating shafts are fixedly provided with the stirring rotating rods in a staggered manner, and a plurality of groups of annular stirring blades are embedded in the stirring rotating rods;

the stirring rotating shaft comprises an upper stirring rotating shaft and a lower stirring rotating shaft, and the upper stirring rotating shaft is connected with the lower stirring rotating shaft through a coupler; the stirring rotary rod is fixedly connected with the annular stirring blade through an embedding device;

the transportation device comprises a transportation part and a curing part fixed on the transportation part; the conveying part comprises a first conveyor belt and a second conveyor belt, and the first conveyor belt is arranged at the upstream of the second conveyor belt and is arranged right below the forming machine; the cutting machine is fixed at the discharge end of the second conveyor belt; a transition roller is arranged between the first conveyor belt and the second conveyor belt;

the curing part comprises a heating resistor block and a cooling wind tunnel; the heating resistor blocks are fixed on two sides of the first conveyor belt, and the corresponding cooling wind tunnels are arranged on the barrier plates on two sides of the second conveyor belt; and the first conveyor belt and the second conveyor belt are respectively provided with a bearing and conveying device.

Preferably, in order to further achieve the purpose of uniform mixing, the embedding device comprises an embedding fixture block and an embedding slot; the embedded clamping block is fixed on the annular stirring blade, and the embedded clamping groove is fixed on the stirring rotary rod; the embedded clamping block comprises an embedded vertical block and an embedded transverse block, and the corresponding embedded clamping groove comprises an embedded wide groove and an embedded narrow groove; the width of the opening of the embedding wide groove is consistent with that of the embedding transverse block, and the size of the opening of the embedding narrow groove is consistent with that of the embedding vertical block; one side of the embedded vertical block is fixed on the stirring rotary rod, and the other side of the embedded vertical block is fixed with the embedded transverse block; the embedded wide groove and the embedded narrow groove are overlapped and communicated with each other; through the embedding fixture block including embedding riser block and embedding horizontal piece to and including the embedding draw-in groove of embedding wide trough and embedding narrow trough, the embedding device of constitution utilizes the cooperation between embedding wide trough and the embedding horizontal piece, and the cooperation between embedding narrow trough and the embedding riser block, thereby realizes fixing between stirring swing arm and the annular stirring leaf, makes the fixed evenly distributed of annular stirring leaf on the stirring swing arm, thereby indirectly realizes the purpose of stirring.

Preferably, in order to further achieve the purpose of uniform mixing, the stirring rotating rod is fixedly connected with the stirring rotating shaft through a fixing device; the fixing device comprises a fixing block and a fixing annular groove; the fixed block is fixed on the stirring rotary rod, and the corresponding fixed ring groove is fixed on the side surface of the stirring rotary shaft; the fixing ring groove comprises an annular groove and a vertical groove; the vertical grooves are embedded in the side surface of the annular groove and are uniformly distributed in the annular groove in a circumferential manner; the fixed block comprises a clamping block head, a hollow fixed block, a telescopic rod and a retarding spring; the width of the block head is consistent with that of the vertical groove; the fixture block head is fixed on the inner wall of the hollow fixed block through a telescopic rod, the bottom end of the hollow fixed block is fixed on the side surface of the stirring rotary rod, and the retarding spring is arranged around the telescopic rod; one end of the retarding spring is fixed on the bottom surface of the inner wall of the hollow fixing block, and the other end of the retarding spring is fixed on the bottom surface of the clamping block head; through including the fixture block head, the cavity fixed block, the telescopic link and the fixed block that slows down the spring, and the fixed ring channel including annular groove and vertical groove, the fixing device of constitution, utilize the cooperation between fixture block head and the vertical groove, the fixture block head is through the edge of annular groove, thereby receive the extrusion, fixture block head extrusion telescopic link and make the telescopic link shrink, enclose this moment and establish the spring that slows down at the telescopic link also receive pressure and shrink, thereby make the fixture block head accomodate into in the cavity fixed block, when treating that the fixture block head enters into vertical inslot, the fixture block head receives to slow down spring force and is popped out, the telescopic link receives fixture block head elasticity and extends this moment, thereby realize fixture block head and vertical groove formation screens structure, realize the fixed screens between stirring hob and the stirring pivot, thereby indirect realization stirring hob stabilizes the stirring, realize the even purpose of compounding.

Preferably, in order to further achieve the purpose of low energy consumption, the bearing and conveying device comprises a fixed bottom block, an embedded groove and a bearing block; the fixed bottom block abuts against the conveying surfaces of the first conveying belt and the second conveying belt, the center of the fixed block is provided with the embedded groove, and the bearing block is fixed in the embedded groove through the retarding device; the retarding device comprises a retarding telescopic rod and a retarding spring; one end of the slow-down telescopic rod is fixed on the bottom surface of the bearing block, and the other end of the slow-down telescopic rod is fixed at the bottom end of the embedded groove; the periphery of the slow-down telescopic rod is surrounded with the slow-down spring, one end of the slow-down spring is fixed on the bottom surface of the embedded groove, and the other end of the slow-down spring is fixed on the bottom surface of the embedded groove; a heat preservation liquid channel is also arranged in the fixed bottom block, a liquid outlet of the heat preservation liquid channel is arranged on the side wall of the bottom surface of the embedding groove, and a corresponding water inlet is arranged on the surface of the fixed bottom block; the side surface of the fixed bottom block is provided with a heat conduction arc-shaped groove; the heat conduction arc-shaped groove is fixed in the middle of the fixed bottom block; through including the fixed bottom block, the conveyor that bears of embedded groove and carrier block, and including the device that slows down the telescopic link and slow down the spring, utilize the carrier block to bear the weight of, the rethread slows down the linkage between the telescopic link and the slow down spring that slows down the device, realize that the carrier block is fixed in the embedded groove, thereby realize the stable transportation of material, and then the indirect stable rapid heating or the cooling of messenger's material in the heat preservation liquid in heat preservation passageway and embedded groove, simultaneously through setting up the heat conduction arc wall on the fixed bottom block, thereby make the heat preservation liquid passageway in the fixed bottom block and the heat preservation liquid in the embedded groove can more quick acceptance temperature variation, thereby reduce the required time of heating or cooling solidification, realize the purpose of low energy consumption.

Preferably, in order to further achieve the purpose of low energy consumption, the forming machine comprises a bearing split plate, a buffer channel and a forming die; the bearing opening plate is arranged right below a discharge port of the discharge pipeline, and a buffer channel is fixed on the bottom surface of the bearing opening plate; the forming die is fixed at the discharge end of the buffer channel; the buffer channel consists of two curved surface buffer blocks with the same specification; the material is guided to enter the forming die through the buffer channel formed by the curved surface buffer blocks, so that the time for collecting and loading the material again is saved, the rapid conversion of the material from the raw material to the forming die is realized, the process time is saved, and the purpose of low energy consumption is realized.

The utility model has the advantages that:

1. by adopting a raw material mixing device, a forming machine, a conveying device, a cutting machine and a collecting and charging plate; in the raw material mixing device, a stirring part is formed by a stirring rotating shaft comprising an upper stirring rotating shaft and a lower stirring rotating shaft, a stirring rotating rod and annular stirring blades distributed on the stirring rotating rod, the upper stirring rotating shaft and the lower stirring rotating shaft are rotated reversely by using a coupler, and the annular stirring blades are connected with the stirring rotating rod through an embedding device, so that the fixation of the annular stirring blades is realized, and the purpose of uniformly mixing materials is realized; and then through the make-up machine shaping back again, in conveyer, through the transport portion including first conveyer belt, the second conveyer belt, and including heating resistance piece, the solidification portion of cooling wind tunnel, set up the transition roller between first conveyer belt and the second conveyer belt simultaneously, and all set up on first conveyer belt and the second conveyer belt and bear conveyer, and then through the heating passageway that first conveyer belt and heating resistance piece are constituteed, and the cooling passageway that second conveyer belt and cooling wind tunnel are constituteed, realize bearing the purpose of the low consumption of the material on the conveyer, cut out and collect the charging plate through the guillootine and collect at last, realize the purpose that the compounding is even and the low energy consumption.

2. Through the embedding fixture block including embedding riser block and embedding horizontal piece to and including the embedding draw-in groove of embedding wide trough and embedding narrow trough, the embedding device of constitution utilizes the cooperation between embedding wide trough and the embedding horizontal piece, and the cooperation between embedding narrow trough and the embedding riser block, thereby realizes fixing between stirring swing arm and the annular stirring leaf, makes the fixed evenly distributed of annular stirring leaf on the stirring swing arm, thereby indirectly realizes the purpose of stirring.

3. By comprising the clamping block head, the hollow fixing block, the telescopic rod and the fixing block of the retarding spring, and a fixing ring groove comprising an annular groove and a vertical groove, wherein the fixture block head passes through the edge of the annular groove by utilizing the matching between the fixture block head and the vertical groove, thereby being extruded, the clamping block head extrudes the telescopic rod to enable the telescopic rod to contract, at the moment, the buffer spring which is arranged around the telescopic rod is also contracted under the pressure, so that the fixture block head is accommodated in the hollow fixing block, when the fixture block head enters the vertical groove, the fixture block head is popped up by the elasticity of the retarding spring, and at the moment, the telescopic rod is stretched by the elasticity of the fixture block head, thereby realize that the fixture block head forms the screens structure with vertical groove, realize the fixed screens between stirring swing arm and the stirring pivot to indirect realization stirring swing arm is stabilized and is stirred, realizes the even purpose of compounding.

4. Through including the fixed bottom block, the conveyor that bears of embedded groove and carrier block, and including the device that slows down the telescopic link and slow down the spring, utilize the carrier block to bear the weight of, the rethread slows down the linkage between the telescopic link and the slow down spring that slows down the device, realize that the carrier block is fixed in the embedded groove, thereby realize the stable transportation of material, and then the indirect stable rapid heating or the cooling of messenger's material in the heat preservation liquid in heat preservation passageway and embedded groove, simultaneously through setting up the heat conduction arc wall on the fixed bottom block, thereby make the heat preservation liquid passageway in the fixed bottom block and the heat preservation liquid in the embedded groove can more quick acceptance temperature variation, thereby reduce the required time of heating or cooling solidification, realize the purpose of low energy consumption.

5. The material is guided to enter the forming die through the buffer channel formed by the curved surface buffer blocks, so that the time for collecting and loading the material again is saved, the rapid conversion of the material from the raw material to the forming die is realized, the process time is saved, and the purpose of low energy consumption is realized.

Drawings

FIG. 1 is a schematic view of the apparatus of the present invention;

FIG. 2 is a schematic view of a raw material mixing device of the apparatus of the present invention;

FIG. 3 is a schematic view of a transportation device of the apparatus of the present invention;

FIG. 4 is a schematic view of a fixing device in the raw material mixing device according to the present invention;

FIG. 5 is a schematic view of an embedding device in the raw material mixing device of the present invention;

in the figure, 1-raw material mixing device, 11-fixed housing, 111-discharge pipe, 12-stirring part, 121-stirring shaft, 1211-upper stirring shaft, 1212-lower stirring shaft, 1213-coupler, 122-stirring screw, 123-ring-shaped stirring blade, 124-embedding device, 1241-embedding dog, 12411-embedding vertical block, 12412-embedding horizontal block, 1242-embedding slot, 12421-embedding wide slot, 12422-embedding narrow slot, 125-fixing device, 1251-fixing block, 12511-dog head, 12512-hollow fixing block, 12513-telescopic rod, 12514-retarding spring, 1252-fixing annular slot, 12521-annular slot, 12522-vertical slot, 2-forming machine, 21-bearing open plate, 22-buffer channel, 221-curved buffer block, 3-conveying device, 31-conveying part, 311-first conveying belt, 312-second conveying belt, 32-solidifying part, 321-heating resistor block, 322-cooling wind tunnel, 33-bearing conveying device, 331-fixed bottom block, 3311-heat conducting arc-shaped groove, 332-embedded groove, 333-bearing block, 334-retarding device, 3341-retarding telescopic rod, 3342-bearing retarding spring, 335-heat preservation liquid channel, 4-cutting machine and 5-material collecting plate.

Detailed Description

The technical solution of the present invention is described in further detail below with reference to the accompanying drawings, but the scope of the present invention is not limited to the following description.

As shown in fig. 1, 2 and 3, a production system of a damping cloth polishing pad is characterized in that: comprises a raw material mixing device 1 and a forming machine 2 arranged on one side of the raw material mixing device 1; a conveying device 3 is arranged below the forming machine 2; the tail end of the conveying device 3 is provided with a cutting machine 4; the discharge end of the cutting machine 4 is provided with a collecting and charging plate 5;

the raw material mixing device 1 comprises a fixed shell 11 and a stirring part 12 fixed in the fixed shell 11; the bottom of the fixed shell 11 is connected with the feeding end of the forming machine 2 through a discharging pipeline 111; the stirring part 12 comprises a stirring rotating shaft 121, a stirring rotary rod 122 and an annular stirring blade 123; the stirring rotating rods 122 are fixed on the side surfaces of the stirring rotating shaft 121 in a staggered manner, and a plurality of groups of annular stirring blades 123 are embedded in the stirring rotating rods 122;

the stirring rotating shaft 121 comprises an upper stirring rotating shaft 1211 and a lower stirring rotating shaft 1212, and the upper stirring rotating shaft 1211 and the lower stirring rotating shaft 1212 are connected through a coupler 1213; the stirring rotary rod 122 is fixedly connected with the annular stirring blade 123 through an embedding device 124;

the transportation device 3 comprises a transportation part 31 and a curing part 32 fixed on the transportation part 31; the conveying part 31 comprises a first conveyor belt 311 and a second conveyor belt 312, wherein the first conveyor belt 311 is arranged at the upstream of the second conveyor belt 312 and is arranged right below the forming machine 2; the cutting machine 4 is fixed at the discharge end of the second conveyor belt 312; a transition roller 313 is arranged between the first conveyor belt 311 and the second conveyor belt 312;

the curing part 32 comprises a heating resistor block 321 and a cooling air tunnel 322; the heating resistor blocks 321 are fixed on two sides of the first conveyor belt 311, and the corresponding cooling wind tunnels 322 are arranged on the barrier plates 3121 on two sides of the second conveyor belt 312; the first conveyor belt 311 and the second conveyor belt 312 are both provided with a carrying and transporting device 33.

In order to further achieve the purpose of low energy consumption, the forming machine 2 comprises a bearing split plate 21, a buffer channel 22 and a forming die 23; the bearing opening plate 21 is arranged right below the discharge hole of the discharge pipeline 111, and a buffer channel 22 is fixed on the bottom surface of the bearing opening plate 21; the forming die 23 is fixed at the discharge end of the buffer channel 22; the buffer channel 22 is composed of two curved buffer blocks 221 with the same specification; the buffering channel 22 formed by the curved buffering blocks 221 is used for guiding the materials to enter the forming die 23, so that the time for collecting and loading the materials again is saved, the materials are quickly converted from the raw materials to the forming die 23, the process time is saved, and the purpose of low energy consumption is achieved.

As shown in fig. 4, in order to further achieve the purpose of mixing uniformly, the stirring rotating rod 122 is fixedly connected with the stirring rotating shaft 121 through a fixing device 125; the fixing device 125 comprises a fixing block 1251 and a fixing ring groove 1252; the fixed block 1251 is fixed to the stirring rotating rod 122, and the corresponding fixed ring groove 1252 is fixed to the side surface of the stirring rotating shaft 121; the fixing ring-shaped groove 1252 comprises a ring-shaped groove 12521 and a vertical groove 12522; the vertical grooves 12522 are embedded in the side surface of the annular groove 12521 and are uniformly distributed in the annular groove 12521 in a circumferential manner; the fixing block 1251 comprises a block head 12511, a hollow fixing block 12512, a telescopic rod 12513 and a slow-down spring 12514; the width of the latch head 12511 is consistent with the width of the vertical groove 12522; the fixture block head 12511 is fixed on the inner wall of the hollow fixed block 12512 through an expansion link 12513, the bottom end of the hollow fixed block 12512 is fixed on the side surface of the stirring rotary rod 122, and the reducing spring 12514 is surrounded around the expansion link 12513; one end of the slow spring 12514 is fixed on the bottom surface of the inner wall of the hollow fixing block 12512, and the other end is fixed on the bottom surface of the block head 12511; by the fixing device 125 comprising the fixture head 12511, the hollow fixing block 12512, the telescopic rod 12513 and the fixing block 1251 of the retarding spring 12514, and the fixing ring groove 1252 comprising the annular groove 12521 and the vertical groove 12522, by utilizing the matching between the fixture head 12511 and the vertical groove 12522, the fixture head 12511 passes through the edge of the annular groove 12521 to be extruded, the fixture head 12511 extrudes the telescopic rod 12513 to shrink the telescopic rod 12513, at this time, the retarding spring 12514 enclosed in the telescopic rod 12513 is also extruded by pressure, so that the fixture head 12511 is accommodated in the hollow fixing block 12512, when the fixture head 12511 enters the vertical groove 12522, the fixture head 12511 is ejected by the elastic force of the retarding spring 12514, at this time, the telescopic rod 12513 is extended by the elastic force of the fixture head 12511, so that the fixture head 12511 and the vertical groove 12522 form a clamping structure, and the fixed clamping between the stirring rotary rod 122 and the stirring rotary shaft 121 is realized, therefore, the stirring of the stirring rotating rod 122 is indirectly realized, and the purpose of uniform mixing is realized.

As shown in fig. 5, in order to further achieve the purpose of uniform mixing, the embedding device 124 includes an embedding fixture 1241 and an embedding fixture 1242; the embedding fixture block 1241 is fixed on the annular stirring blade 123, and the embedding fixture groove 1242 is fixed on the stirring rotary rod 122; the embedded fixture block 1241 comprises an embedded vertical block 12411 and an embedded transverse block 12412, and the corresponding embedded slot 1242 comprises an embedded wide slot 12421 and an embedded narrow slot 12422; the opening of the wide embedding slot 12421 is the same as the width of the horizontal embedding block 12412, and the opening of the narrow embedding slot 12422 is the same as the width of the vertical embedding block 12411; one side of the embedded vertical block 12411 is fixed on the stirring rotary rod 122, and the other side is fixed with the embedded transverse block 12412; the embedded wide slot 12421 and the embedded narrow slot 12422 are overlapped and communicated with each other; through the embedding fixture block 1241 including embedding riser 12411 and embedding horizontal piece 12412, and including embedding draw-in groove 1242 of embedding wide groove 12421 and embedding narrow groove 12422, the embedding device 124 of constitution utilizes the cooperation between embedding wide groove 12421 and the embedding horizontal piece 12412, and the cooperation between embedding narrow groove 12422 and the embedding riser 12411, thereby realize the fixed between stirring jib 122 and the annular stirring leaf 123, make the fixed evenly distributed of annular stirring leaf 123 on stirring jib 122, thereby indirectly realize the even mesh of stirring.

For further achieving the purpose of low energy consumption, the carrying and transporting device 33 includes a fixed bottom block 331, an embedded groove 332, and a carrying block 333; the fixed bottom block 331 abuts against the conveying surfaces of the first conveying belt 311 and the second conveying belt 312, the embedded groove 332 is formed in the center of the fixed bottom block 331, and the bearing block 333 is fixed in the embedded groove 332 through a slowing device 334; the slowing device 334 comprises a slowing telescopic rod 3341 and a bearing slowing spring 3342; one end of the slow-down telescopic rod 3341 is fixed on the bottom surface of the bearing block 333, and the other end is fixed at the bottom end of the embedded groove 332; the periphery of the slow-down telescopic rod 3341 is surrounded with the load-bearing slow-down spring 3342, one end of the load-bearing slow-down spring 3342 is fixed on the bottom surface of the embedded groove 332, and the other end of the load-bearing slow-down spring 3342 is fixed on the bottom surface of the embedded groove 332; a heat preservation liquid channel 335 is further formed in the fixed bottom block 331, a liquid outlet of the heat preservation liquid channel 335 is arranged on the side wall of the bottom surface of the embedded groove 332, and a corresponding water inlet is arranged on the surface of the fixed bottom block 331; a heat-conducting arc-shaped groove 3311 is arranged on the side surface of the fixed bottom block 331; the heat-conducting arc-shaped groove 3311 is fixed in the middle of the fixed bottom block 331; through including fixed bottom block 331, embedded groove 332 and bearing block 333 bear conveyer 33, and including slowing down telescopic link 3341 and bearing and slowing down device 334 that spring 3342 slows down, utilize bearing block 333 to bear the weight of, rethread slows down telescopic link 3341 and bears the linkage that slows down between the spring 3342 that slows down device 334, realize that bearing block 333 fixes in embedded groove 332, thereby realize the stable transportation of material, and then the indirect stable rapid heating or the cooling that makes the material in heat preservation passageway 335 and the heat preservation liquid of embedded groove 332, simultaneously through setting up heat conduction arc groove 3311 on fixed bottom block 331, thereby make heat preservation liquid passageway 335 in the fixed bottom block 331 and the heat preservation liquid of embedded groove 332 can be more quick the temperature change of accepting, thereby reduce the required time of heating or cooling solidification, realize the purpose of low energy consumption.

Working process or principle: when the material is required to be produced, the upper stirring rotating shaft 1211 is connected with the output end of the motor, the upper stirring rotating shaft 1211 is connected with the lower stirring rotating shaft 1212 through the coupler 1213, then the stirring rotating rod 122 is matched with the fixing device 125, the fixture block head 12511 passes through the edge of the annular groove 12521 by the matching between the fixture block head 12511 and the vertical groove 12522, thereby being extruded, the fixture block 12511 extrudes the telescopic rod 12513 to make the telescopic rod 12513 contract, at the moment, the buffer spring 12514 enclosed on the telescopic rod 12513 is also contracted by pressure, so that the cartridge head 12511 is received in the hollow fixture block 12512, when the cartridge head 12511 enters the vertical groove 12522, the latch head 12511 is ejected by the elastic force of the slow spring 12514, and the telescopic rod 12513 is extended by the elastic force of the latch head 12511, thereby realizing that the clamping block head 12511 and the vertical groove 12522 form a clamping structure and realizing the fixed clamping between the stirring rotary rod 122 and the stirring rotary shaft 121; according to the proportion of the materials to be stirred, a proper number of annular stirring blades 123 pass through the embedded fixture block 1241 of the embedding device 124, the embedded vertical block 12411 and the embedded transverse block 12412 of the embedded block 121 and the embedded wide groove 12421 and the embedded narrow groove 12422 of the embedded clamp groove 1242, and the annular stirring blades 123 are fixed and uniformly distributed on the stirring rotary rod 122 and further the annular stirring blades 123 are fixed on the stirring rotary rod 122 by the matching between the embedded wide groove 12421 and the embedded transverse block 12412 and the matching between the embedded narrow groove 12422 and the embedded vertical block 12411, so that the uniform mixing of the materials is realized by starting the motor to stir;

then, the uniformly stirred materials are extracted by a pump set of a discharge pipeline 111 and enter a bearing open close plate 21 of a forming machine 2 to be stacked, after the material amount is proper, the bearing open plate 21 is opened, so that the materials enter a forming mold 23 to be formed through a buffer channel 22 consisting of two curved surface buffer blocks 221 with the same specification, and then the formed polishing pad enters a conveying device 3;

the material falls onto the bearing block 333 of the bearing and transporting device 33 first, at this moment, the bearing block 333 extrudes the retarding telescopic rod 3341 of the retarding device 334 in the embedded groove 332, at this moment, the retarding spring 3342 on the bottom surface of the bearing block 333 is stressed and contracted, so that the stability of the material on the bearing block 333 is maintained by utilizing the linkage between the retarding telescopic rod 3341 and the retarding spring 3342, finally, the heat preservation liquid is filled in the heat preservation liquid channel 335 on the fixed bottom block 331, the embedded groove 332 is filled with the heat preservation liquid, at this moment, the motors of the first conveying belt 311 and the second conveying belt 312 of the transporting part 31 are started, meanwhile, the heating resistance block 321 of the curing part 32 of the first conveying belt 311 works with the cold area wind tunnel 322, the heat conducting arc-shaped groove 3311 on the side surface of the fixed bottom block 331 carries out heat exchange fully, and the purpose of low energy consumption is realized.

The foregoing is illustrative of the preferred embodiments of the present invention, and it is to be understood that the invention is not limited to the precise forms disclosed herein, and that various other combinations, modifications, and environments may be resorted to, falling within the scope of the invention as defined by the appended claims. But that modifications and variations may be effected by those skilled in the art without departing from the spirit and scope of the invention, which is to be limited only by the claims appended hereto.

Claims (10)

1. A production system of damping cloth polishing pad which characterized in that: comprises a raw material mixing device (1) and a forming machine (2) arranged on one side of the raw material mixing device (1); a conveying device (3) is arranged below the forming machine (2); the tail end of the conveying device (3) is provided with a cutting machine (4); the discharge end of the cutting machine (4) is provided with a collecting and charging plate (5);

the raw material mixing device (1) comprises a fixed shell (11) and a stirring part (12) fixed in the fixed shell (11); the bottom of the fixed shell (11) is connected with the feeding end of the forming machine (2) through a discharging pipeline (111); the stirring part (12) comprises a stirring rotating shaft (121), a stirring rotary rod (122) and an annular stirring blade (123); the stirring rotating rods (122) are fixedly distributed on the side surfaces of the stirring rotating shaft (121) in a staggered manner, and a plurality of groups of annular stirring blades (123) are embedded in the stirring rotating rods (122);

the stirring rotating shaft (121) comprises an upper stirring rotating shaft (1211) and a lower stirring rotating shaft (1212), and the upper stirring rotating shaft (1211) is connected with the lower stirring rotating shaft (1212) through a coupler (1213); the stirring rotary rod (122) is fixedly connected with the annular stirring blade (123) through an embedding device (124);

the transportation device (3) comprises a transportation part (31) and a curing part (32) fixed on the transportation part (31); the conveying part (31) comprises a first conveying belt (311) and a second conveying belt (312), wherein the first conveying belt (311) is arranged at the upstream of the second conveying belt (312) and is arranged right below the forming machine (2); the cutting machine (4) is fixed at the discharge end of the second conveyor belt (312); a transition roller (313) is arranged between the first conveyor belt (311) and the second conveyor belt (312);

the curing part (32) comprises a heating resistor block (321) and a cooling wind tunnel (322); the heating resistor blocks (321) are fixed on two sides of the first conveyor belt (311), and the corresponding cooling wind tunnels (322) are arranged on the barrier plates (3121) on two sides of the second conveyor belt (312); and the first conveyor belt (311) and the second conveyor belt (312) are both provided with a bearing and conveying device (33).

2. The system for producing a damping cloth polishing pad according to claim 1, wherein: the embedding device (124) comprises an embedding clamping block (1241) and an embedding clamping groove (1242); the embedded fixture block (1241) is fixed on the annular stirring blade (123), and the embedded fixture groove (1242) is fixed on the stirring rotary rod (122); the embedded clamping block (1241) comprises an embedded vertical block (12411) and an embedded transverse block (12412), and the corresponding embedded clamping groove (1242) comprises an embedded wide groove (12421) and an embedded narrow groove (12422); the opening of the wide embedding slot (12421) is consistent with the width of the horizontal embedding block (12412), and the opening of the narrow embedding slot (12422) is consistent with the width of the vertical embedding block (12411); one surface of the embedded vertical block (12411) is fixed on the stirring rotary rod (122), and the other surface is fixed with the embedded transverse block (12412); the embedded wide slot (12421) and the embedded narrow slot (12422) are overlapped and communicated with each other.

3. The system for producing a damping cloth polishing pad according to claim 1, wherein: the stirring rotary rod (122) is fixedly connected with the stirring rotary shaft (121) through a fixing device (125); the fixing device (125) comprises a fixing block (1251) and a fixing ring groove (1252); the fixed block (1251) is fixed on the stirring rotary rod (122), and the corresponding fixed annular groove (1252) is fixed on the side surface of the stirring rotary shaft (121); the fixed annular groove (1252) comprises an annular groove (12521) and a vertical groove (12522); the vertical grooves (12522) are embedded in the side surface of the annular groove (12521) and are uniformly distributed in the annular groove (12521) in a circumferential manner.

4. The production system of a damping cloth polishing pad as set forth in claim 3, wherein: the fixing block (1251) comprises a block head (12511), a hollow fixing block (12512), an expansion rod (12513) and a slow-down spring (12514); the width of the block head (12511) is consistent with that of the vertical groove (12522); the block head (12511) is fixed on the inner wall of the hollow fixed block (12512) through an expansion link (12513), the bottom end of the hollow fixed block (12512) is fixed on the side surface of the stirring rotary rod (122), and the reducing spring (12514) is surrounded around the expansion link (12513); one end of the slow-down spring (12514) is fixed on the bottom surface of the inner wall of the hollow fixed block (12512), and the other end is fixed on the bottom surface of the block head (12511).

5. The production system of a damping cloth polishing pad according to claim 3 or 4, wherein: the bearing and transporting device (33) comprises a fixed bottom block (331), an embedded groove (332) and a bearing block (333); the fixed bottom block (331) abuts against the conveying surfaces of the first conveying belt (311) and the second conveying belt (312), the embedded groove (332) is formed in the center of the fixed bottom block (331), and the bearing block (333) is fixed in the embedded groove (332) through the retarding device (334).

6. The production system of a damping cloth polishing pad as set forth in claim 5, wherein: the slowing device (334) comprises a slowing telescopic rod (3341) and a bearing slowing spring (3342); one end of the slow-down telescopic rod (3341) is fixed on the bottom surface of the bearing block (333), and the other end of the slow-down telescopic rod is fixed at the bottom end of the embedded groove (332); slow down telescopic link (3341) around enclose be equipped with bear slow down spring (3342), bear slow down spring (3342) one end fix embedded groove (332) bottom surface, the other end fix embedded groove (332) bottom surface.

7. The production system of a damping cloth polishing pad as set forth in claim 6, wherein: still seted up heat preservation liquid passageway (335) in fixed bottom block (331), the liquid outlet setting of heat preservation liquid passageway (335) be in embedded groove (332) bottom surface lateral wall, the corresponding water inlet setting is in the surface of fixed bottom block (331).

8. The production system of a damping cloth polishing pad as set forth in claim 5, wherein: a heat-conducting arc-shaped groove (3311) is arranged on the side surface of the fixed bottom block (331); the heat-conducting arc-shaped groove (3311) is fixed in the middle of the fixed bottom block (331).

9. The system for producing a damping cloth polishing pad according to claim 1, wherein: the forming machine (2) comprises a bearing open-close plate (21), a buffer channel (22) and a forming die (23); the bearing opening plate (21) is arranged right below a discharge hole of the discharge pipeline (111), and a buffer channel (22) is fixed on the bottom surface of the bearing opening plate (21); the forming die (23) is fixed at the discharge end of the buffer channel (22).

10. The system for producing a damping cloth polishing pad according to claim 9, wherein: the buffer channel (22) is composed of two curved buffer blocks (221) with the same specification.

Images