CN114857147B - Glue and arrange steel wire fiber production facility - Google Patents
Glue and arrange steel wire fiber production facility Download PDFInfo
- Publication number
- CN114857147B CN114857147B CN202210416292.1A CN202210416292A CN114857147B CN 114857147 B CN114857147 B CN 114857147B CN 202210416292 A CN202210416292 A CN 202210416292A CN 114857147 B CN114857147 B CN 114857147B
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- 229910000831 Steel Inorganic materials 0.000 title claims abstract description 313
- 239000010959 steel Substances 0.000 title claims abstract description 313
- 238000007380 fibre production Methods 0.000 title claims description 21
- 239000003292 glue Substances 0.000 title claims description 6
- 239000000835 fiber Substances 0.000 claims abstract description 94
- 238000009826 distribution Methods 0.000 claims abstract description 65
- 238000001035 drying Methods 0.000 claims abstract description 32
- 238000004519 manufacturing process Methods 0.000 claims abstract description 14
- 238000001179 sorption measurement Methods 0.000 claims description 89
- 238000007789 sealing Methods 0.000 claims description 45
- 230000005540 biological transmission Effects 0.000 claims description 40
- XEEYBQQBJWHFJM-UHFFFAOYSA-N Iron Chemical group [Fe] XEEYBQQBJWHFJM-UHFFFAOYSA-N 0.000 claims description 25
- 230000000149 penetrating effect Effects 0.000 claims description 16
- 239000000463 material Substances 0.000 claims description 5
- 230000001105 regulatory effect Effects 0.000 claims description 2
- 229920000297 Rayon Polymers 0.000 claims 2
- 239000002994 raw material Substances 0.000 abstract description 6
- 230000032258 transport Effects 0.000 description 9
- 238000005520 cutting process Methods 0.000 description 4
- 238000000034 method Methods 0.000 description 4
- 238000010521 absorption reaction Methods 0.000 description 3
- 238000007599 discharging Methods 0.000 description 3
- 230000009286 beneficial effect Effects 0.000 description 2
- 238000010008 shearing Methods 0.000 description 2
- 239000011083 cement mortar Substances 0.000 description 1
- 230000000739 chaotic effect Effects 0.000 description 1
- 239000010960 cold rolled steel Substances 0.000 description 1
- 230000007547 defect Effects 0.000 description 1
- 238000005516 engineering process Methods 0.000 description 1
- 238000009776 industrial production Methods 0.000 description 1
- 229910052742 iron Inorganic materials 0.000 description 1
- 230000005389 magnetism Effects 0.000 description 1
- 238000003801 milling Methods 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 238000005096 rolling process Methods 0.000 description 1
- 238000003756 stirring Methods 0.000 description 1
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Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16B—DEVICES FOR FASTENING OR SECURING CONSTRUCTIONAL ELEMENTS OR MACHINE PARTS TOGETHER, e.g. NAILS, BOLTS, CIRCLIPS, CLAMPS, CLIPS OR WEDGES; JOINTS OR JOINTING
- F16B11/00—Connecting constructional elements or machine parts by sticking or pressing them together, e.g. cold pressure welding
- F16B11/006—Connecting constructional elements or machine parts by sticking or pressing them together, e.g. cold pressure welding by gluing
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B21—MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
- B21F—WORKING OR PROCESSING OF METAL WIRE
- B21F15/00—Connecting wire to wire or other metallic material or objects; Connecting parts by means of wire
- B21F15/02—Connecting wire to wire or other metallic material or objects; Connecting parts by means of wire wire with wire
- B21F15/06—Connecting wire to wire or other metallic material or objects; Connecting parts by means of wire wire with wire with additional connecting elements or material
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02W—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO WASTEWATER TREATMENT OR WASTE MANAGEMENT
- Y02W30/00—Technologies for solid waste management
- Y02W30/50—Reuse, recycling or recovery technologies
- Y02W30/91—Use of waste materials as fillers for mortars or concrete
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- Engineering & Computer Science (AREA)
- General Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
- Drying Of Solid Materials (AREA)
- Ropes Or Cables (AREA)
Abstract
The invention discloses a production device for sticky steel wire fibers, which comprises: the steel wire adjusting piece comprises a support receiving piece and a steel wire direction adjusting piece, wherein the steel wire direction adjusting piece rotates in the support receiving piece to adsorb steel wire fibers in hydrosol and discharge the steel wire fibers one by one in the same direction; a wire distribution member including a distribution support and a rotary distribution member receiving the wire fibers discharged from the support receiver on the distribution support and closely arranging a predetermined number of the wire fibers; and the steel wire transferring and drying part comprises a steel wire transferring part and a drying part, the steel wire transferring part receives the steel wire fibers which are closely arranged and discharged by the rotary distribution part, and transfers the steel wire fibers which are closely arranged to the drying part to be dried into sticky steel wire fibers. The invention has the advantages of simple structure, high automation degree, low production cost and wide range of raw materials for producing the bonded steel wire fibers.
Description
Technical Field
The invention relates to the technical field of steel wire fiber production, in particular to a sticky row steel wire fiber production device.
Background
The steel fiber is a fiber having a length-to-diameter ratio (a ratio of a fiber length to a fiber diameter, when the fiber section is non-circular, a diameter converted into an equivalent section circle area) of 40 to 80, which is produced by a method of cutting a thin steel wire, shearing a cold-rolled strip steel, milling a steel ingot, or rapidly condensing molten steel. The steel wire fiber is a novel building raw material, and when concrete is poured, the steel wire fiber is mixed with cement mortar, so that the structural strength of the concrete can be greatly enhanced. However, the single steel wire fiber is easy to agglomerate and disperse unevenly during the process of mixing with concrete, and the single steel wire fiber is inconvenient to package and transport.
The bonded steel wire fibers are a technology of bonding single steel wire fibers into rows by adopting water-soluble glue, can ensure that the fibers are not agglomerated and are uniformly dispersed in concrete stirring in use, can improve the impact resistance and fatigue resistance of concrete and improve the impermeability of the concrete, and are widely applied to roads, highway slope protection bridges, tunnels, airports, ports, iron sleepers and the like.
At present, the production of the sticky arranged steel wire fiber depends on a thin steel wire cutting method and a cold-rolled strip steel shearing production method, namely, before longitudinal cutting of the sticky arranged steel wire fiber, closely arranged steel wires or longitudinally sheared cold-rolled strip steel are bonded in rows by using water-soluble glue, and then longitudinal cutting is carried out by using a rolling machine. However, the production of the sticky row steel wire fiber needs expensive cold-rolled steel wires and steel belts as production raw materials, so that the sticky row steel wire has high production cost, and the sticky row steel wire fiber is not beneficial to large-area popularization and use. How to process the steel wire fiber made by the raw material with lower price and the leftover material in the industrial production process into the sticky row steel wire fiber has important practical value.
Disclosure of Invention
In order to overcome the defects, the invention provides a production device for sticky steel wire fibers, which specifically adopts the following technical scheme:
a bonded steel wire fiber production apparatus comprising:
the steel wire adjusting piece comprises a supporting receiving piece and a steel wire direction adjusting piece, wherein the steel wire direction adjusting piece rotates in the supporting receiving piece to adsorb steel wire fibers in hydrosol and discharge the steel wire fibers in the same direction one by one;
a wire distributing member provided on the support receiver, including a distributing support and a rotary distributing member receiving the wire fibers discharged from the support receiver on the distributing support and closely arranging a predetermined number of the wire fibers;
and the steel wire transferring and drying piece is arranged on the supporting and receiving piece and comprises a steel wire transferring piece and a drying piece, the steel wire transferring piece receives the steel wire fibers which are closely arranged and discharged by the rotating and distributing piece, and transfers the steel wire fibers which are closely arranged into the drying piece to be dried into sticky steel wire fibers.
Preferably, the support receiver includes a wire receiving box, a wire supporting leg, and a relay sub, the wire receiving box being disposed on the ground through the wire supporting leg, a steel wire receiving opening is communicated with one end of the steel wire receiving box and used for receiving conveyed single steel wire fibers; the steel wire receiving box is filled with hydrosol.
Preferably, the relay distribution part comprises a steel wire gathering pipe, a relay pipe, a first magnetic coil and a relay sealing plate, wherein one end of the steel wire gathering pipe is arranged at the other end of the steel wire receiving box in a penetrating manner, one end of the relay pipe is arranged at the other end of the steel wire gathering pipe in a penetrating manner, and the first magnetic coil is sleeved on the relay pipe.
Preferably, the relay sealing plates are arc-plate-shaped, one end of one relay sealing plate is arranged at the other port of the relay pipe, one end of the other relay sealing plate is fixedly arranged at the other port of the relay pipe, the two relay sealing plates are symmetrically distributed, and the centers of the two relay sealing plates coincide; two be provided with first sealing strip on the relay closing plate same side, two be provided with the second sealing strip on the relay closing plate opposite side.
Preferably, the steel wire direction regulating piece comprises a steel wire adsorption pipe, an electromagnetic adsorption piece, a rotary power piece and a longitudinal pushing piece, and the steel wire adsorption pipe is arranged on the end face of the steel wire receiving box in a penetrating manner through a first rotating shaft arranged on the end face; the outer side wall of the steel wire adsorption tube is provided with a steel wire sliding groove, the axis of the steel wire sliding groove is parallel to the axis of the steel wire adsorption tube, and the plurality of steel wire sliding grooves are uniformly distributed along the circumferential direction of the steel wire adsorption tube;
the electromagnetic adsorption piece comprises a first electromagnetic adsorption piece and a second electromagnetic adsorption piece, and the first electromagnetic adsorption piece and the second electromagnetic adsorption piece are both arranged on the steel wire adsorption tube; the first electromagnetic adsorption piece comprises an iron core and a second magnetic coil, one end of the iron core is arranged on the inner wall of one end of the steel wire adsorption tube, and the iron cores are uniformly distributed around the inner wall of the steel wire adsorption tube in the circumferential direction; the plurality of second magnetic force coils are sleeved on the iron core one by one correspondingly; the second electromagnetic adsorption pieces are the same as the first electromagnetic adsorption pieces in structure, and the iron cores of the second electromagnetic adsorption pieces are uniformly distributed around the inner wall of the other end of the steel wire adsorption tube in the circumferential direction; and the second magnetic coils of the second electromagnetic adsorption pieces are sleeved on the iron core one by one correspondingly, and the second magnetic coils in different rows along the circumferential direction are connected in parallel by current.
Preferably, the rotary power part comprises a rotary motor, a first worm and a first worm wheel, the rotary motor is arranged on the steel wire receiving box, the first worm is arranged on a rotating shaft of the rotary motor, the first worm wheel is sleeved on the first rotating shaft, and the first worm wheel is meshed with the first worm; the longitudinal pushing piece comprises a pushing spiral plate and an adjusting spiral pipe, the pushing spiral plate is in a spiral sheet shape, a pushing through hole is formed in the pushing spiral plate along the axis, and the pushing spiral plate is sleeved on the inner wall of the steel wire receiving box through a supporting connecting rod after being sleeved on the steel wire adsorption pipe; the inner diameter of the adjusting spiral pipe is not smaller than the sum of the outer diameter of the steel wire adsorption pipe and the diameter of the steel wire fiber, the adjusting spiral pipe is arranged on the pushing spiral plate, the axis of the adjusting spiral pipe coincides with the axis of the pushing spiral plate, and meanwhile, a release plate is arranged at one end of the adjusting spiral pipe.
Preferably, the dispensing support comprises a dispensing support plate and a dispensing support leg, the dispensing support plate being disposed on the ground by the dispensing support leg; the rotary distribution piece comprises a rotary wheel, a second worm and a distribution motor, wherein distribution relay grooves are formed in the side face of the rotary wheel, the distribution relay grooves are rectangular groove-shaped, and the distribution relay grooves are uniformly distributed on the rotary wheel along the circumferential direction; a third magnetic coil is arranged around each distribution relay slot; third sealing strips are arranged on the side faces of the rotating wheels between every two adjacent distribution relay grooves; the rotating wheel is arranged on the distribution supporting plate in a penetrating mode through a second rotating shaft arranged on the end face, the side face of the rotating wheel is embedded in the relay sealing plate in a matching mode, the second worm wheel is sleeved on the second rotating shaft, the distribution motor is arranged on the distribution supporting plate, the second worm is arranged on the rotating shaft of the distribution motor, and the second worm is meshed with the second worm wheel.
Preferably, the steel wire transfer part comprises a transfer transmission frame, transmission rollers, a transmission belt, a third worm gear, a transmission motor, a third worm and a receiving part, the transfer transmission frame is arranged on the ground below the steel wire distribution part, the two transmission rollers are arranged at two ends of the transfer transmission frame through third rotating shafts arranged at two ends, and the transmission belt is sleeved on the two transmission rollers simultaneously; the third worm wheel suit is in the third pivot, drive machine sets up transport on the gear frame, the third worm sets up in drive machine's the pivot, and the third worm with the meshing of third worm wheel.
Preferably, the receiving part comprises a receiving pipe, a fourth magnetic coil, an attracting part and a first automatic telescopic rod, one end of the receiving pipe is arranged on the transmission belt, and the receiving pipes are arranged at equal intervals along the transmission belt; it is a plurality of fourth magnetic coil corresponds the suit one by one and is a plurality of accept the outside of the pipe.
Preferably, the sucking and biting piece comprises a sucking and biting block, a second automatic telescopic rod and a sucking and biting male connector, the sucking and biting block is embedded in the bearing pipe, a sucking and biting relay cavity is arranged in the sucking and biting block, a plurality of sucking and biting through holes are formed in the side surface of the sucking and biting block in a penetrating manner, a sucking and biting female connector is arranged on the other side surface of the sucking and biting plate in a penetrating manner, and the free end of the sucking and biting female connector successively penetrates through the bottom of the bearing pipe and the transmission belt; the second automatic telescopic rod is arranged on the transfer transmission frame, one end of the sucking and eating male joint is vertically arranged at the top end of the second automatic telescopic rod, a sucking and eating hose is connected to the side face of the sucking and eating male joint in a penetrating manner, and the free end of the sucking and eating hose is connected with the sucking and eating pump in a penetrating manner; the first automatic telescopic rod is arranged on the transfer transmission frame, a pushing relay rod is arranged at the top end of the first automatic telescopic rod, and the first automatic telescopic rod can push the suction and feeding block to slide on the receiving pipe through the pushing relay rod; the drying part comprises a drying rack and a drying box, the drying box spans the transmission belt through the drying rack and dries the steel wire fibers wrapped with hydrosol in the bearing pipe.
The invention at least comprises the following beneficial effects:
1) The production equipment for the sticky row steel wire fibers has the advantages of simple structure, high automation degree, low production cost and wide range of raw materials for the sticky row steel wire fiber production;
2) The production equipment of the bonding and exhausting steel wire fiber is provided with a steel wire receiving box, a steel wire collecting pipe, a relay pipe, a steel wire adsorption pipe, an electromagnetic adsorption part, a longitudinal pushing part, a rotary distribution part, a steel wire transfer part and a drying part, wherein the steel wire fiber is put into the steel wire receiving box filled with hydrosol, automatically adsorbed on one end of the rotary steel wire adsorption pipe, transferred to the other end of the steel wire adsorption pipe by the longitudinal pushing part, released to automatically enter the rotary distribution part from the steel wire collecting pipe through the relay pipe, and finally transferred to the drying part by the steel wire transfer part to be dried to prepare the bonding and exhausting steel wire fiber; the production of the sticky row steel wire fibers does not depend on thin steel wires and cold-rolled strips, the production cost of the sticky row steel wire fibers is effectively reduced, and the application range of the sticky row steel wire fiber production to raw materials is remarkably improved.
Additional advantages, objects, and features of the invention will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following or may be learned from practice of the invention.
Drawings
FIG. 1 is a front view of a bonded steel wire fiber production apparatus according to the present invention;
FIG. 2 is a front view of the apparatus for producing bonded steel wire fibers according to the present invention;
FIG. 3 is a top view of the bonding wire fiber production apparatus of the present invention;
FIG. 4 is a schematic view of a front side three-dimensional structure of a bonded steel wire fiber production apparatus according to the present invention;
FIG. 5 is a schematic view of a rear side three-dimensional structure of the bonded steel wire fiber production equipment of the present invention;
FIG. 6 isbase:Sub>A schematic view ofbase:Sub>A cross-sectional perspective view taken along the direction A-A in FIG. 3 of the apparatus for producing bonded steel wire fibers according to the present invention;
FIG. 7 is a schematic view of a cross-sectional three-dimensional structure in the direction B-B in FIG. 3 of the apparatus for producing bonded steel wire fibers according to the present invention;
FIG. 8 is a schematic view showing the connection relationship between a connecting pipe and a transmission belt in the bonding row steel wire fiber production equipment of the present invention;
FIG. 9 is a schematic view of the connection relationship between the carrier pipe and the transmission belt in the bonded steel wire fiber production apparatus of the present invention.
Wherein: 1-a steel wire receiving box, 2-a steel wire supporting leg, 3-a steel wire receiving port, 4-a steel wire collecting tube, 5-a relay tube, 6-a first magnetic coil, 7-a relay sealing plate, 8-a third sealing strip, 9-a steel wire absorbing tube, 10-an iron core, 11-an iron core of a second electromagnetic absorbing part, 12-a rotating motor, 13-a first worm, 14-a first worm gear, 15-a pushing spiral plate, 16-an adjusting spiral tube, 17-a releasing plate, 18-a distributing supporting plate, 20-a rotating wheel, 21-a second worm gear, 22-a second worm, 23-a distributing motor, 24-a distributing relay groove, 25-a transfer driving frame, 26-a driving roller, 27-a driving belt, 28-a third worm gear, 29-a driving motor, 30-a third worm, 31-a receiving tube, 32-a fourth magnetic coil, 33-a first automatic telescopic rod, 34-a second automatic telescopic rod, 35-an absorbing male joint, 36-an absorbing female joint, 37-a steel wire absorbing hose, 38-a steel wire absorbing fiber-a first rotary rod, and 40-a drying shaft.
Detailed Description
Technical solutions of the present invention will be described in detail below by way of embodiments with reference to the accompanying drawings. It should be noted that the description of the embodiments is provided to help understanding of the present invention, but the present invention is not limited thereto.
The term "and/or" herein is merely an association describing an associated object, meaning that three relationships may exist, e.g., a and/or B, may mean: a exists alone, B exists alone, and A and B exist at the same time, and the term "/and" is used herein to describe another association object relationship, which means that two relationships may exist, for example, A/and B, may mean: a alone, and both a and B alone, and further, the character "/" in this document generally means that the former and latter associated objects are in an "or" relationship.
According to fig. 1-9, a glue and arrange steel wire fibre production facility, including steel wire adjustment piece, steel wire distributor and steel wire transportation stoving, steel wire distributor sets up on the steel wire adjustment piece, the steel wire transport stoving with steel wire distributor is connected. The steel wire adjusting piece comprises a supporting receiving piece and a steel wire direction adjusting piece, and the steel wire direction adjusting piece is arranged on the supporting receiving piece. The support receives the piece and includes steel wire receiving box 1, steel wire supporting leg 2 and relay distribution spare, the steel wire supporting leg 2 with relay distribution spare all sets up on the steel wire receiving box 1. The steel wire receiving box 1 is horizontally arranged on the ground through steel wire supporting legs 2. The steel wire receiving box 1 is rectangular box-shaped, the lateral wall link up and is provided with steel wire receiving port 3 on 1 one end of steel wire receiving box, steel wire receiving port 3 is used for receiving single steel wire fibre 38 that the fortune came. The steel wire receiving box 1 is filled with hydrosol.
The relay distribution piece comprises a steel wire collecting pipe 4, a relay pipe 5, a first magnetic coil 6 and a relay sealing plate 7, wherein the steel wire collecting pipe 4 is arranged on the steel wire receiving box 1, the relay pipe 5 is arranged on the steel wire collecting pipe 4, and the first magnetic coil 6 and the relay sealing plate 7 are arranged on the relay pipe 5. One end of the steel wire gathering pipe 4 is arranged on the lower side wall of the other end of the steel wire receiving box 1 in a penetrating mode, and the steel wire fibers 38 entering from one end of the steel wire gathering pipe 4 are discharged from the other end of the steel wire gathering pipe 4. The size of the cross section of the other end of the steel wire collecting pipe 4 is smaller than that of the cross section of one end of the steel wire collecting pipe 4. The inner width of the relay pipe 5 is not less than the diameter of the steel wire fibers 38, and the inner length of the relay pipe 5 is not less than the length of the steel wire fibers 38. One end of the relay pipe 5 is vertically arranged at the other end of the steel wire gathering pipe 4 in a penetrating manner, so that the steel wire gathering pipe 4 can gather the steel wire fibers 38 into the relay pipe 5. The first magnetic coil 6 is fixedly sleeved on the relay pipe 5. When the first magnetic coil 6 is energized with forward direct current to generate a magnetic field, the steel wire fibers 38 which are attracted to slowly sink in hydrosol are accelerated to enter the relay pipe 5 one by one. And can increase the speed at which the steel wire fibres 38 are transported from the relay pipe 5 into the steel wire distribution element.
The relay sealing plate 7 is in a circular arc plate shape, and two relay sealing plates 7 are arranged. One end of the relay sealing plate 7 is fixedly arranged at the other end of the relay pipe 5. One end of the other relay sealing plate 7 is fixedly arranged at the other port of the relay pipe 5, the two relay sealing plates 7 are symmetrically distributed, and the centers of the two relay sealing plates 7 are overlapped. The same side of the two relay sealing plates 7 and the port at the other end of the relay pipe 5 are provided with a first sealing strip, and the other side of the two relay sealing plates 7 and the port at the other end of the relay pipe 5 are provided with a second sealing strip. The first sealing strip and the second sealing strip are matched with the steel wire distribution piece to seal two side faces of the other end of the relay pipe 5, so that hydrosol in the steel wire receiving box 1 and the steel wire gathering pipe 4 is prevented from flowing out of two end edges of the other end of the relay pipe 5. The third sealing strip 8 on the steel wire distributing part is matched with the relay sealing plate 7 to seal the other two side surfaces of the other end opening of the relay pipe 5, so that hydrosol in the steel wire receiving box 1 and the steel wire gathering pipe 4 is prevented from flowing out of the two side edges of the other end of the relay pipe 5. Finally, the sealing and leak-proof function of the other end of the relay pipe 5 is realized.
The steel wire is transferred to the piece and is included steel wire absorption piece, rotary power spare and vertical lapse, the steel wire absorbs the piece rotary power spare with vertical lapse all sets up on the steel wire receiving box 1. The steel wire adsorbs the piece and includes steel wire adsorption tube 9 and electromagnetic adsorption piece, steel wire adsorption tube 9 sets up on the steel wire receiver box 1, the electromagnetic adsorption piece sets up on the steel wire adsorption tube 9. All be provided with first pivot 39 on the steel wire adsorption tube 9 both ends face, steel wire adsorption tube 9 passes through both ends first pivot 39 runs through the setting respectively on the face of steel wire receiving box 1 both ends, makes steel wire adsorption tube 9 can pass through first pivot 39 is in the circumferential direction rotates in the steel wire receiving box 1. The outer side wall of the steel wire adsorption pipe 9 is provided with a steel wire sliding groove, and the depth of the steel wire sliding groove is smaller than the radius of the steel wire fiber 38. The steel wire sliding tray axis with 9 axes of steel wire adsorption tube are parallel, and are a plurality of the steel wire sliding tray is followed 9 circumference evenly distributed of steel wire adsorption tube. The steel wire adsorption tube 9 is divided into a steel wire adsorption adjusting area and a steel wire release area along the longitudinal direction, the steel wire adsorption adjusting area is located below the steel wire receiving opening 3, and the steel wire release area is located above the steel wire gathering tube 4.
The electromagnetic adsorption piece includes first electromagnetic adsorption piece and second electromagnetic adsorption piece, first electromagnetic adsorption piece with the second electromagnetic adsorption piece all sets up on the steel wire adsorption tube 9. First electromagnetic adsorption spare includes iron core 10 and second magnetic coil, iron core 10 is rectangular block-shaped, iron core 10 one end is fixed to be set up the steel wire adsorbs the adjustment zone on the 9 inner walls of steel wire adsorption tube, and iron core 10 vertical line with the coincidence of 9 radial lines of steel wire adsorption tube. The iron core 10 is provided with a plurality ofly, and is a plurality of the iron core 10 centers on 9 inner walls circumference evenly distributed of steel wire adsorption tube. The second magnetic force coil is provided with a plurality of, and a plurality of second magnetic force coil corresponds the suit one by one on iron core 10. When the second magnetic coil is switched on with direct current to generate a magnetic field, the circumferential magnetic force of the steel wire adsorption tube 9 is uniformly distributed. So as to adsorb the steel wire fiber 38 slowly sinking in the hydrosol entering the steel wire receiving box 1 from the steel wire receiving port 3 on the outer wall of the steel wire adsorption tube 9. The second electromagnetic adsorption piece is the same as the first electromagnetic adsorption piece in structure, and a plurality of iron cores 11 of the second electromagnetic adsorption piece surround the steel wire release area and are uniformly distributed on the inner wall of the steel wire adsorption tube 9 in the circumferential direction. The second magnetic coils of the second electromagnetic adsorption pieces are fixedly sleeved on the iron core one by one correspondingly, and the second magnetic coils in different rows along the circumferential direction are connected in parallel. The steel wire adsorption pipe 9 loses magnetism section by section along the circumferential direction, and the adsorbed steel wire fibers 38 are released section by section along the circumferential direction by the steel wire adsorption pipe 9.
The rotary power part comprises a rotary motor 12, a first worm 13 and a first worm wheel 14, the rotary motor 12 is arranged on the steel wire receiving box 1, the first worm 13 is arranged on a rotating shaft of the rotary motor 12, the first worm wheel 14 is fixedly sleeved on the first rotating shaft 39, and the first worm wheel 14 is meshed with the first worm 13. Vertical lapse piece is including advancing spiral plate 15 and adjustment spiral pipe 16, it is the spiral slice to advance spiral plate 15, it is not less than to advance 15 pitch of spiral plate 38 length of steel wire fibre, it is provided with along the axis and advances the through hole to advance spiral plate 15, it with to advance 15 axis coincidence of spiral plate to advance the through hole axis, it is not less than to advance the through hole internal diameter the outer diameter of steel wire adsorption tube 9. The pushing spiral plate 15 is sleeved on the inner wall of the steel wire receiving box 1 through a supporting connecting rod after the steel wire adsorption pipe 9 is sleeved. When the steel wire absorption tube 9 absorbs the steel wire fibers 38 and then rotates in the circumferential direction, the steel wire fibers 38 are pushed by the pushing spiral plate 15 and pushed from the steel wire absorption adjustment area to the steel wire release area. Since the steel wire fibers 38 are in a chaotic stacked state when they are just adsorbed on the outer wall of the steel wire adsorption tube 9, the adjustment coil 16 is required to adjust the layering. The inner diameter of the adjusting spiral pipe 16 is not less than the sum of the outer diameter of the steel wire adsorption pipe 9 and the diameter of the steel wire fiber 38, and the number of turns of the adjusting spiral pipe 16 is not less than one. The adjustment spiral pipe 16 sets up on advancing spiral plate 15, and the adjustment spiral pipe 16 axis with advance 15 axis coincidence of spiral plate, simultaneously adjustment spiral pipe 16 one end is provided with release board 17, release board 17 one end is connected pass spiral pipe one and serve, and release board 17 lateral wall is connected pass on the spiral plate 15, in order to increase adjustment spiral pipe 16 a port with opening interval between the steel wire adsorption tube 9, so that adsorb on steel wire adsorption tube 9 steel wire fiber 38 gets into smoothly in the adjustment spiral pipe 16. The steel wire fibers 38 in the disordered and stacked state are pushed circumferentially after entering the releasing plate 17, and the steel wire fibers 38 pushed circumferentially are absorbed longitudinally by the second magnetic coil, embedded into the steel wire sliding groove, and pushed continuously to the steel wire releasing area by the pushing spiral plate 15. The steel wire fibers 38 pushed to the steel wire release area are controlled by the magnetic force of the second magnetic coil of the second electromagnetic adsorption piece, the steel wire fibers 38 are released when the steel wire fibers rotate to the position of the lower side of the steel wire adsorption tube 9, the steel wire fibers 38 slowly enter the relay tube 5 through the steel wire gathering tube 4 in hydrosol, and then enter the steel wire distribution piece through the relay tube 5.
The wire dispensing member comprises a dispensing support member disposed on the support receiving member and a rotary dispensing member disposed on the dispensing support member. The distribution support comprises a distribution support plate 18 and a distribution support leg by means of which the distribution support plate 18 is arranged on the floor. Rotatory distribution spare includes swiveling wheel 20, second worm wheel 21, second worm 22 and distribution motor 23, swiveling wheel 20 radius with relay sealing plate 7 medial surface radius is the same, be provided with distribution relay groove 24 on the swiveling wheel 20 side, distribution relay groove 24 is the rectangle slot form, distribution relay groove 24 cross section width is not less than steel wire fibre 38 diameter, distribution relay groove 24 cross section length is not less than steel wire fibre 38 length. The distribution relay slots 24 are evenly distributed in the circumferential direction on the rotary wheel 20. A third magnetic coil is arranged around each distribution relay slot 24, when a forward direct current is introduced into the third magnetic coil to generate a magnetic field, the steel wire fibers 38 are adsorbed, so that the steel wire fibers 38 in the relay pipe 5 are accelerated to enter the distribution relay slots 24, when the distribution relay slots 24 rotate to a preset position, a reverse direct current is introduced into the third magnetic coil to generate a magnetic field, so that the steel wire fibers 38 in the distribution relay slots 24 are pushed out to enter the steel wire transfer drying piece. Adjacent two between the distribution relay groove 24 all be provided with third sealing strip 8 on the swiveling wheel 20 side, third sealing strip 8 with the cooperation of relay closing plate 7 can play 5 another port of relay pipe two sides in addition are sealed, in order to prevent steel wire receiving box 1 with the hydrosol in the steel wire is put together the pipe 4 by the both sides limit of the 5 other ends of relay pipe flows. Finally, the sealing and leak-proof function of the other end of the relay pipe 5 is realized. The rotor 20 is horizontally inserted into the distribution support plate 18 through a second rotation shaft provided at an end surface thereof, and the rotor 20 is fitted and fitted into the relay sealing plate 7 at a side surface thereof, so that the rotor 20 can be rotated in a sealed manner on the distribution support plate 18 and in the relay sealing plate 7 through the second rotation shaft. The second worm wheel 21 is fixedly sleeved on the second rotating shaft, the distribution motor 23 is fixedly arranged on the distribution supporting plate 18, the second worm 22 is arranged on the rotating shaft of the distribution motor 23, and the second worm 22 is meshed with the second worm wheel 21.
The steel wire is transported and is dried piece and include that the steel wire transports piece and stoving piece 40, stoving piece 40 is connected on the steel wire transports the piece. The steel wire transports the piece including transporting the driving medium and accepting the piece, it sets up to accept the piece transport on the driving medium. The transportation driving medium includes transportation driving frame 25, driving roller 26, drive belt 27, third worm wheel 28, driving motor 29 and third worm 30, transportation driving frame 25 sets up the subaerial of steel wire distribution piece below, two driving roller 26 all sets up through the third pivot that both ends set up transportation driving frame 25 both ends make driving roller 26 can pass through the third pivot is in circumferential direction on the transportation driving frame 25. The driving belt 27 is simultaneously sleeved on the two driving rollers 26. The third worm wheel 28 is fixedly sleeved on the third rotating shaft, the transmission motor 29 is arranged on the transfer transmission frame 25, the third worm 30 is arranged on the rotating shaft of the transmission motor 29, and the third worm 30 is meshed with the third worm wheel 28.
The adapting piece comprises an adapting pipe 31, a fourth magnetic coil 32, an attracting piece and a first automatic telescopic rod 33, wherein the adapting pipe 31 is arranged on the transmission belt 27, the fourth magnetic coil 32 is arranged on the adapting pipe 31, the attracting piece is arranged on the adapting pipe 31, and the first automatic telescopic rod 33 is arranged on the transmission frame 25. The adapting pipe 31 is in a rectangular groove shape, the inner diameter width of the adapting pipe 31 is not less than the diameter of the steel wire fiber 38, and the inner diameter length of the adapting pipe 31 is not less than the length of the steel wire fiber 38. One end of the adapting pipe 31 is vertically arranged on the transmission belt 27. The plurality of the sockets 31 are uniformly arranged at equal intervals along the belt 27. The fourth magnetic coils 32 are sleeved outside the plurality of receiving pipes 31 one by one. When the fourth magnetic coil 32 is energized with direct current to generate a magnetic field, the steel wire fibers 38 are accelerated to enter the adapting pipe 31 from the distribution relay groove 24, or the dried sticky steel wire fibers 38 are pushed out from the adapting pipe 31. The receiver 31 can correspond to the distribution relay tank 24 one by one.
Inhale and eat piece and eat male joint 35 including inhaling and eat piece, the piece of eating is the rectangle cubic, it inlays the dress and is in to inhale and eat the piece in the adapting tube 31, it inhales and eats the relay chamber to inhale to be provided with in the piece of eating, it inhales to be provided with a plurality of through-holes of eating of inhaling on the piece side to inhale, and is a plurality of inhale and eat the through-hole inhale and eat all with it inhales and eats the relay chamber and link up, it inhales and is provided with on the board another side and inhale and eats female joint 36, inhale and eat female joint 36 with it wears the relay chamber to inhale and link up. The free end of the suction female joint 36 penetrates through the bottom of the bearing pipe 31 and the transmission belt 27 in sequence. The vertical setting of second automatic telescopic link 34 is in transport on the driving frame 25, it is in to inhale the vertical setting of male joint 35 one end the 34 tops of second automatic telescopic link, it inhales the male joint 35 side through connection of inhaling to have inhales and eats hose 37 to inhale, it inhales hose 37 free end and inhales and eats pump through connection to inhale. When the second automatic telescopic rod 34 is extended, the sucking and biting male joint 35 is pushed to be inserted into the sucking and biting female joint 36, and the sucking and biting pump sucks excess hydrosol in the adapting tube 31 through the sucking and biting hose 37, the sucking and biting male joint 35, the sucking and biting female joint 36 and the sucking and biting through hole, so that the usage amount of hydrosol is saved, and the sticking and discharging steel wire fibers 38 can be conveniently pushed out from the adapting tube 31. First automatic telescopic link 33 sets up transport on the driving frame 25, first automatic telescopic link 33 top is provided with pushes away material relay bar, it is not more than to push away material relay bar diameter inhale and eat 36 cross section sizes of female joint. After the steel wire fibers 38 are dried by the drying part 40 in the receiving tube 31, the first automatic telescopic rod 33 extends to push the pushing relay rod against the suction-suction female joint 36, the suction-suction block is pushed by the suction-suction female joint 36 to move from the bottom of the receiving tube 31 to the notch, then thrust is applied to the adhering and discharging steel wire fibers 38, and finally the first automatic telescopic rod 33 and the fourth magnetic coil 32 are matched to push the adhering and discharging steel wire fibers 38 out of the receiving tube 31.
The drying part 40 comprises a drying rack and a drying box, the drying box is fixedly mounted on the drying rack, and the drying box straddles one end of the transmission belt 27 through the drying rack, and dries the steel wire fibers 38 wrapped with hydrosol in the bearing pipe 31 to form sticky steel wire fibers 38. Because the drying box adopts the prior art, the description is omitted here.
While embodiments of the invention have been described above, it is not intended to be limited to the details shown, described and illustrated herein, but is to be accorded the widest scope consistent with the principles and novel features herein disclosed, and to such extent that such modifications are readily available to those skilled in the art, and it is not intended to be limited to the details shown and described herein without departing from the general concept as defined by the appended claims and their equivalents.
Claims (8)
1. The utility model provides a glue row steel wire fiber production facility which characterized in that includes:
the steel wire adjusting piece comprises a supporting receiving piece and a steel wire direction adjusting piece, wherein the steel wire direction adjusting piece rotates in the supporting receiving piece to adsorb steel wire fibers in hydrosol and discharge the steel wire fibers in the same direction one by one;
a wire distributing member provided on the support receiver, including a distributing support and a rotating distributing member receiving the wire fibers discharged from the support receiver on the distributing support and closely arranging a predetermined number of the wire fibers;
the steel wire transferring and drying part is arranged on the supporting and receiving part and comprises a steel wire transferring part and a drying part, the steel wire transferring part receives the steel wire fibers which are discharged by the rotary distribution part and are closely arranged, and transfers the steel wire fibers which are closely arranged into the drying part to be dried into sticky steel wire fibers;
the supporting and receiving piece comprises a steel wire receiving box, a steel wire supporting leg and a relay distribution piece, the steel wire receiving box is arranged on the ground through the steel wire supporting leg, a steel wire receiving opening is communicated with one end of the steel wire receiving box, and the steel wire receiving opening is used for receiving single steel wire fibers conveyed; hydrosol is filled in the steel wire receiving box; the steel wire direction regulating part comprises a steel wire adsorption pipe, an electromagnetic adsorption part, a rotary power part and a longitudinal pushing part, and the steel wire adsorption pipe is arranged on the end face of the steel wire receiving box in a penetrating manner through a first rotating shaft arranged on the end face; the outer side wall of the steel wire adsorption tube is provided with a steel wire sliding groove, the axis of the steel wire sliding groove is parallel to the axis of the steel wire adsorption tube, and the plurality of steel wire sliding grooves are uniformly distributed along the circumferential direction of the steel wire adsorption tube; the dispensing support comprises a dispensing support plate and a dispensing support leg, the distribution support plate is arranged on the ground through the distribution support leg; the rotary distribution piece comprises a rotary wheel, a second worm and a distribution motor, wherein distribution relay grooves are formed in the side face of the rotary wheel, the distribution relay grooves are rectangular groove-shaped, and the distribution relay grooves are uniformly distributed on the rotary wheel along the circumferential direction; the steel wire transferring part comprises a transferring transmission frame, transmission rollers, a transmission belt, a third worm wheel, a transmission motor, a third worm and a receiving part, the transferring transmission frame is arranged on the ground below the steel wire distributing part, the two transmission rollers are arranged at the two ends of the transferring transmission frame through third rotating shafts arranged at the two ends, and the transmission belt is sleeved on the two transmission rollers simultaneously; the third worm wheel suit is in the third pivot, drive machine sets up transport on the gear frame, the third worm sets up in drive machine's the pivot, and the third worm with the meshing of third worm wheel.
2. The bonded steel wire fiber production facility of claim 1, wherein the relay distributor comprises a steel wire gathering pipe, a relay pipe, a first magnetic coil and a relay sealing plate, one end of the steel wire gathering pipe is penetratingly disposed at the other end of the steel wire receiving box, one end of the relay pipe is penetratingly disposed at the other end of the steel wire gathering pipe, and the first magnetic coil is sleeved on the relay pipe.
3. The bonded steel wire fiber production facility according to claim 2, wherein the relay sealing plates are in the shape of circular arc plates, one end of one relay sealing plate is arranged at the other end of the relay pipe, the other end of the other relay sealing plate is fixedly arranged at the other end of the relay pipe, and the two relay sealing plates are symmetrically distributed while the centers of the circles of the two relay sealing plates coincide; two be provided with first sealing strip on the relay closing plate same side, two be provided with the second sealing strip on the relay closing plate opposite side.
4. The viscose rayon fiber production equipment of claim 3, wherein the electromagnetic adsorption member comprises a first electromagnetic adsorption member and a second electromagnetic adsorption member, and the first electromagnetic adsorption member and the second electromagnetic adsorption member are both arranged on the steel wire adsorption pipe; the first electromagnetic adsorption piece comprises an iron core and a second magnetic coil, one end of the iron core is arranged on the inner wall of one end of the steel wire adsorption tube, and the iron cores are uniformly distributed around the inner wall of the steel wire adsorption tube in the circumferential direction; the plurality of second magnetic force coils are sleeved on the iron core one by one correspondingly; the second electromagnetic adsorption pieces are the same as the first electromagnetic adsorption pieces in structure, and the iron cores of the second electromagnetic adsorption pieces are uniformly distributed around the inner wall of the other end of the steel wire adsorption tube in the circumferential direction; and the second magnetic coils of the second electromagnetic adsorption pieces are sleeved on the iron core one by one correspondingly, and the second magnetic coils in different rows along the circumferential direction are connected in parallel by current.
5. The bonded steel wire fiber production facility of claim 4, wherein the rotary power member comprises a rotary motor, a first worm and a first worm wheel, the rotary motor is arranged on the steel wire receiving box, the first worm is arranged on a rotating shaft of the rotary motor, the first worm wheel is sleeved on the first rotating shaft, and the first worm wheel is meshed with the first worm; the longitudinal pushing piece comprises a pushing spiral plate and an adjusting spiral pipe, the pushing spiral plate is in a spiral sheet shape, a pushing through hole is formed in the pushing spiral plate along the axis, and the pushing spiral plate is sleeved on the inner wall of the steel wire receiving box through a supporting connecting rod after being sleeved on the steel wire adsorption pipe; the inner diameter of the adjusting spiral pipe is not smaller than the sum of the outer diameter of the steel wire adsorption pipe and the diameter of the steel wire fibers, the adjusting spiral pipe is arranged on the pushing spiral plate, the axis of the adjusting spiral pipe coincides with the axis of the pushing spiral plate, and meanwhile, a release plate is arranged at one end of the adjusting spiral pipe.
6. The bonded steel wire fiber production facility of claim 5 wherein a third magnetic coil is disposed around each of the distribution relay slots; third sealing strips are arranged on the side faces of the rotating wheels between every two adjacent distribution relay grooves; the rotating wheel is arranged on the distribution supporting plate in a penetrating mode through a second rotating shaft arranged on the end face, the side face of the rotating wheel is embedded in the relay sealing plate in a matching mode, the second worm wheel is sleeved on the second rotating shaft, the distribution motor is arranged on the distribution supporting plate, the second worm is arranged on the rotating shaft of the distribution motor, and the second worm is meshed with the second worm wheel.
7. The bonded steel wire fiber production equipment according to claim 6, wherein the receiving member comprises a receiving pipe, a fourth magnetic coil, a suction member and a first automatic telescopic rod, one end of the receiving pipe is arranged on the transmission belt, and a plurality of receiving pipes are arranged at equal intervals along the transmission belt; and the fourth magnetic coils are sleeved outside the carrying pipes one by one correspondingly.
8. The production equipment of viscose steel wire fibers according to claim 7, wherein the sucking and eating member comprises a sucking and eating block, a second automatic telescopic rod and a sucking and eating male joint, the sucking and eating block is embedded in the receiving pipe, a sucking and eating relay cavity is arranged in the sucking and eating block, a plurality of sucking and eating through holes are arranged on the side surface of the sucking and eating block in a penetrating manner, a sucking and eating female joint is arranged on the other side surface of the sucking and eating block in a penetrating manner, and the free end of the sucking and eating female joint penetrates through the bottom of the receiving pipe and the transmission belt in sequence; the second automatic telescopic rod is arranged on the transfer transmission frame, one end of the sucking and eating male joint is vertically arranged at the top end of the second automatic telescopic rod, a sucking and eating hose is connected to the side face of the sucking and eating male joint in a penetrating manner, and the free end of the sucking and eating hose is connected with the sucking and eating pump in a penetrating manner; the first automatic telescopic rod is arranged on the transfer transmission frame, a material pushing relay rod is arranged at the top end of the first automatic telescopic rod, and the first automatic telescopic rod can push the sucking and gripping block to slide on the receiving pipe through the material pushing relay rod; the drying part comprises a drying rack and a drying box, the drying box spans the transmission belt through the drying rack and dries the steel wire fibers wrapped with hydrosol in the bearing pipe.
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| Application Number | Priority Date | Filing Date | Title |
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| CN202210416292.1A CN114857147B (en) | 2022-04-20 | 2022-04-20 | Glue and arrange steel wire fiber production facility |
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| CN202210416292.1A CN114857147B (en) | 2022-04-20 | 2022-04-20 | Glue and arrange steel wire fiber production facility |
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