阅读说明：本技术 一种纺织用纺织布传送设备 (Weaving is with weaving cloth conveying equipment ) 是由 刘赛赛 于 2021-01-11 设计创作，主要内容包括：本发明提供了一种纺织用纺织布传送设备,其结构包括配电箱、主体外壳、端板、传送机构、驱动器,配电箱后端上方通过螺钉固定于端板前端,端板外壁嵌套固定于主体外壳内部,传送机构后端嵌固卡合于端板前端上方,驱动器后端通过卡扣卡合固定于端板前端下方,本发明在对纺织材料进行运输时,通过设备的启动运转会使主轴带动滑座进行旋转,通过滑座对吸热环进行摩擦,使得吸热环能进行膨胀而挤压挤压块,挤压块受到挤压会产生电压进而将设备运转的静电进行增强,使得在传送带上放置的纺织布会因传送带表面附带的静电而被吸附,避免纺织布在移动的过程中,因空气注入接触面的缘故降低接触面面积而导致纺织布脱落的问题出现。(The invention provides textile cloth conveying equipment for spinning, which structurally comprises a distribution box, a main body shell, an end plate, a conveying mechanism and a driver, wherein the upper part of the rear end of the distribution box is fixed at the front end of the end plate through screws, the outer wall of the end plate is embedded and fixed in the main body shell, the rear end of the conveying mechanism is embedded and clamped above the front end of the end plate, and the rear end of the driver is clamped and fixed below the front end of the end plate through a buckle, the spindle can drive the sliding seat to rotate through the starting operation of the equipment, the heat absorption ring is rubbed through the sliding seat, so that the heat absorption ring can expand to extrude the extrusion block, the extrusion block can generate voltage to strengthen the static electricity of the equipment operation, so that the textile cloth placed on the conveyor belt can be adsorbed due to the static electricity attached to the surface of the conveyor belt, and the textile cloth is prevented from moving, the problem of falling off of the woven cloth due to the reduction of the contact surface area due to the injection of air into the contact surface occurs.)

1. Textile fabric conveying equipment for spinning structurally comprises a distribution box (1), a main body shell (2), an end plate (3), a conveying mechanism (4) and a driver (5), wherein the upper part of the rear end of the distribution box (1) is fixed at the front end of the end plate (3) through screws, the outer wall of the end plate (3) is embedded and fixed in the main body shell (2), the rear end of the conveying mechanism (4) is embedded and fixedly clamped above the front end of the end plate (3), and the rear end of the driver (5) is fixedly arranged below the front end of the end plate (3) through clamping and buckling;

transport mechanism (4) are by assembly plate (11), adsorption device (12), drive belt (13), fixed pin (14), unload structure (15) and constitute, adsorption device (12) assemble in assembly plate (11) left side rear end completely, drive belt (13) inner wall interference fit is in adsorption device (12) outer wall, fixed pin (14) outer wall is embedded and is fixed in assembly plate (11) inner wall, it cooperates in drive belt (13) right side inner wall to unload structure (15) outer wall nestification.

2. A textile fabric transfer apparatus as claimed in claim 1 wherein: the adsorption mechanism (12) is composed of a driving wheel (a1), a connecting rod (a2) and an electrostatic mechanism (a3), the inner wall of the driving wheel (a1) is welded and fixed at the upper end of the connecting rod (a2), and the outer wall of the lower end of the connecting rod (a2) is nested and assembled on the inner wall of the electrostatic mechanism (a 3).

3. A textile fabric transfer apparatus as claimed in claim 2, wherein: the static mechanism (a3) comprises an outer ring (b1), an extrusion block (b2), a heat absorption ring (b3), a sliding seat (b4) and a spindle (b5), wherein the lower end of the outer ring (b1) is fixed at the upper end of a connecting rod (a2) through clamping, the lower end of the extrusion block (b2) is fixedly embedded in the inner wall of the outer ring (b1), the heat absorption ring (b3) is completely assembled inside the outer ring (b1), the inner wall of the sliding seat (b4) is movably matched with the inner side outer wall of the heat absorption ring (b3), and the outer wall of the spindle (b5) is fixedly welded on the left side of the sliding seat (b 4).

4. A textile fabric transfer apparatus as claimed in claim 1 wherein: unloading structure (15) comprise nested ring (c1), fixing base (c2), horizontal pole (c3), vibrations equipment (c4), nested ring (c1) inner wall welded fastening is in fixing base (c2) left side, fixing base (c2) right side horizontal pole (c3) are embedded and are fixed in fixing base (c2) left side, horizontal pole (c3) right side activity block is in vibrations equipment (c4) outer wall.

5. A textile fabric transfer apparatus as claimed in claim 4 wherein: vibrations equipment (c4) comprises eccentric ring (d1), lantern ring (d2), pivot (d3), elevating system (d4), eccentric ring (d1) inner wall nestification is fixed in elevating system (d4) right side, lantern ring (d2) inner wall interference is fixed in pivot (d3) outer wall, elevating system (d4) left side is inlayed and is admittedly blocked in lantern ring (d2) outer wall.

6. A textile fabric transfer apparatus as claimed in claim 5, wherein: elevating system (d4) comprises shell (e1), magnetic ring (e2), magnetic stripe (e3), movable block (e4), guide arm (e5), the inside lower extreme of magnetic ring (e2) lower extreme embedded fixed in shell (e1), magnetic stripe (e3) right side is fixed in movable block (e4) left side outer wall through the buckle, movable block (e4) right side lower extreme outer wall welded fastening is in guide arm (e5) upper left end, guide arm (e5) outer wall assembles completely in shell (e1) inner wall.

Technical Field

The invention relates to the field of spinning, in particular to textile cloth conveying equipment for spinning.

Background

Weaving cloth no matter in that link all need use transfer apparatus to carry out the transmission transportation to weaving cloth in the production line, transfer apparatus is one, through rotating the position at the motor and loading the pivot, and the surface assembly drive belt at the pivot, and the work of motor can drive the pivot and rotate and transport the weaving cloth that the drive belt upper end was placed through the motion of drive belt, but soft because of the material of drive belt, can't load things such as trip at the upper end, lead to the drive belt at the in-process of transportation weaving cloth, because of the weight of weaving cloth is lighter, drive weaving cloth at the drive belt and carry out the in-process that fast migration was carried out to weaving cloth, partial air can get into the position that weaving cloth and drive belt contacted because of weaving cloth's removal, the area of contact of weaving cloth and weaving drive belt has been reduced, and the problem that leads to cloth to drop from the drive belt top takes.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides textile fabric conveying equipment for spinning, which solves the problem that in the process of conveying textile fabric by a driving belt, due to the fact that the driving belt is made of soft materials and cannot be loaded with clamping hooks and other objects at the upper end, part of air enters the position where the textile fabric is contacted with the driving belt due to the movement of the textile fabric in the process that the driving belt drives the textile fabric to move rapidly because the weight of the textile fabric is light, and the problem that the textile fabric falls off from the upper side of the driving belt due to the fact that the contact area of the textile fabric and the driving belt is reduced.

Aiming at the above purpose, the invention is realized by the following technical scheme: a textile fabric conveying device for spinning structurally comprises a distribution box, a main body shell, an end plate, a conveying mechanism and a driver, wherein the upper part of the rear end of the distribution box is fixed at the front end of the end plate through screws;

transport mechanism comprises assembly plate, adsorption equipment, drive belt, fixed pin, the structure of unloading, adsorption equipment assembles in assembly plate left side rear end completely, drive belt inner wall interference fit is in adsorption equipment outer wall, the fixed pin outer wall is embedded to be fixed in the assembly plate inner wall, the nested cooperation of the structure outer wall of unloading is in drive belt right side inner wall.

Preferably, the adsorption mechanism comprises three transmission wheels, three connecting rods and three electrostatic mechanisms, wherein the inner walls of the transmission wheels are welded and fixed at the upper ends of the connecting rods, the outer walls of the lower ends of the connecting rods are nested and assembled on the inner walls of the electrostatic mechanisms, and the three connecting rods are annularly arranged on the inner walls of the transmission wheels.

Preferably, the electrostatic mechanism comprises an outer ring, an extrusion block, a heat absorption ring, three sliding seats and a spindle, wherein the lower end of the outer ring is fixed at the upper end of the connecting rod in a clamping manner through a buckle, the lower end of the extrusion block is fixedly embedded in the inner wall of the outer ring, the heat absorption ring is completely assembled in the outer ring, the inner wall of the sliding seat is movably matched with the outer wall of the inner side of the heat absorption ring, the outer wall of the spindle is fixedly welded on the left side of the sliding seat, and the extrusion blocks are made of piezoelectric materials and are annularly arranged on the inner wall of.

Preferably, the discharging structure comprises a nested ring, a fixed seat, two transverse rods and vibration equipment, wherein the inner wall of the nested ring is welded and fixed on the left side of the fixed seat, the transverse rod on the right side of the fixed seat is fixedly embedded and fixed on the left side of the fixed seat, the right side of the transverse rods is movably clamped and connected with the outer wall of the vibration equipment, and the two transverse rods are arranged at two ends of the vibration equipment in an opposite mode.

Preferably, the vibration device comprises an eccentric ring, a sleeve ring, a rotating shaft and a lifting mechanism, wherein the inner wall of the eccentric ring is fixed on the right side of the lifting mechanism in an embedded mode, the inner wall of the sleeve ring is fixed on the outer wall of the rotating shaft in an interference mode, the left side of the lifting mechanism is fixedly clamped on the outer wall of the sleeve ring in an embedded mode, the eccentric ring is of an oval structure, and the thickness of the upper end of the eccentric ring is twice that of the lower end.

Preferably, the lifting mechanism comprises a shell, a magnetic ring, a magnetic stripe, a movable block and a guide rod, wherein the lower end of the magnetic ring is fixedly embedded in the lower end of the inside of the shell, the right side of the magnetic stripe is fixed on the outer wall of the left side of the movable block through a buckle, the outer wall of the right lower end of the movable block is welded and fixed on the upper left end of the guide rod, the outer wall of the guide rod is completely assembled on the inner wall of the shell, and the guide rod is of a V.

Advantageous effects

Compared with the prior art, the invention has the following beneficial effects:

when the textile material is transported, the spindle can drive the sliding seat to rotate through the starting operation of the equipment, the heat absorption ring is rubbed through the sliding seat, the heat absorption ring can expand to extrude the extrusion block, the extrusion block can generate voltage through extrusion, and further static electricity generated by the operation of the equipment is enhanced, so that textile cloth placed on the conveying belt can be adsorbed due to the static electricity attached to the surface of the conveying belt, and the problem that the textile cloth falls off due to the fact that the area of the contact surface is reduced due to the fact that air is injected into the contact surface in the moving process of the textile cloth is solved.

Drawings

FIG. 1 is a schematic structural view of a textile fabric conveying apparatus for textile use according to the present invention.

Fig. 2 is a schematic front view of the conveying mechanism of the present invention.

FIG. 3 is a schematic cross-sectional view of the adsorption mechanism of the present invention.

Fig. 4 is a schematic cross-sectional structure of the inventive electrostatic mechanism.

Fig. 5 is a schematic sectional structure view of the discharging structure of the invention.

Fig. 6 is a schematic front view of the vibration device of the present invention.

Fig. 7 is a partial sectional structural schematic view of the inventive lift mechanism.

In the figure: distribution box-1, main body shell-2, end plate-3, conveying mechanism-4, driver-5, assembly plate-11, adsorption mechanism-12, transmission belt-13, fixing pin-14, unloading structure-15, transmission wheel-a 1, connecting rod-a 2, electrostatic mechanism-a 3, outer ring-b 1, extrusion block-b 2, heat absorption ring-b 3, sliding seat-b 4, main shaft-b 5, nesting ring-c 1, fixed seat-c 2, cross rod-c 3, vibration device-c 4, eccentric ring-d 1, lantern ring-d 2, rotating shaft-d 3, lifting mechanism-d 4, shell-e 1, magnetic ring-e 2, magnetic strip-e 3, movable block-e 4 and guide rod-e 5.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it is obvious that the described embodiments are some, not all embodiments of the present invention, and all other embodiments obtained by those skilled in the art without creative efforts based on the embodiments of the present invention belong to the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Example 1

As shown in the accompanying drawings 1 to 4, the invention provides textile cloth conveying equipment for spinning, which structurally comprises a distribution box 1, a main body shell 2, an end plate 3, a conveying mechanism 4 and a driver 5, wherein the upper part of the rear end of the distribution box 1 is fixed at the front end of the end plate 3 through screws, the outer wall of the end plate 3 is embedded and fixed in the main body shell 2, the rear end of the conveying mechanism 4 is embedded and clamped above the front end of the end plate 3, and the rear end of the driver 5 is clamped and fixed below the front end of the end plate 3 through a buckle;

transport mechanism 4 comprises assembly plate 11, adsorption device 12, drive belt 13, fixed pin 14, the structure of unloading 15, adsorption device 12 assembles in 11 left sides rear ends of assembly plate completely, 13 inner walls interference fit in 12 outer walls of adsorption device of drive belt, 14 outer walls of fixed pin are embedded and are fixed in 11 inner walls of assembly plate, 15 outer walls nestification of the structure of unloading are in coordination in 13 right side inner walls of drive belt.

The adsorption mechanism 12 comprises a driving wheel a1, a connecting rod a2 and an electrostatic mechanism a3, wherein the inner wall of the driving wheel a1 is welded and fixed at the upper end of the connecting rod a2, the outer wall of the lower end of the connecting rod a2 is nested and assembled on the inner wall of the electrostatic mechanism a3, the number of the connecting rods a2 is three, the three connecting rods are annularly arranged on the inner wall of the driving wheel a1, the three ends are arranged to be triangular, so that the stability is improved, and the driving wheel a1 can be connected with the electrostatic mechanism a 3.

The static mechanism a3 comprises an outer ring b1, an extrusion block b2, a heat absorption ring b3, a sliding seat b4 and a spindle b5, wherein the lower end of the outer ring b1 is fixed at the upper end of a connecting rod a2 through snap-fit, the lower end of the extrusion block b2 is fixedly embedded in the inner wall of an outer ring b1, the heat absorption ring b3 is completely assembled inside the outer ring b1, the inner wall of the sliding seat b4 is movably matched with the inner side outer wall of the heat absorption ring b3, the outer wall of the spindle b5 is fixed on the left side of the sliding seat b4 through welding, the extrusion block b2 is made of piezoelectric materials, three extrusion blocks are arranged on the inner wall of the outer ring b1 in an annular mode, and the extrusion block b2 generates voltage after being extruded through material characteristics, so that free static electricity on.

The following examples are set forth: the external power supply is connected to the distribution box 1 through a connecting wire, so that the whole equipment is powered on, the driver 5 can be started after the equipment is powered on, the conveying mechanism 4 is driven to work and move by the operation of the driver 5 after the driver 5 is started, the adsorption mechanism 12 can work due to the rotation of the spindle b5 in the working and moving process of the conveying mechanism 4, when the spindle b5 rotates, the spindle b5 can drive the sliding seat b4 to rotate, the sliding seat b4 is attached to the surface of the heat absorption ring b3 to rub, so that the heat absorption ring b3 generates heat due to the rubbing, after the heat is generated, the heat absorption ring b3 expands due to the influence of heat energy, the heat absorption ring b3 expands in volume and extrudes to the extrusion block b2, after the extrusion block b2 is extruded, the extrusion block b2 can generate voltage due to the special property of the material, the voltage of the extrusion block b2 can attract free static electricity carried by the equipment during the working and enhance the static electricity intensity, after the static intensity is increased, static electricity is conducted to the driving wheel a1 through the connecting rod a2, static electricity is attached to the driving belt 13 assembled on the surface of the driving wheel a1, and after the driving belt 13 has the static electricity, textile cloth placed on the surface of the driving belt 13 is adsorbed to the surface of the driving belt 13 due to the static electricity attached to the driving belt 13, so that the problem that air enters the contact surface of the driving belt 13 and the textile cloth, the contact area is reduced, and the textile cloth falls off is avoided.

Example 2

As shown in fig. 5 to 7: unloading structure 15 comprises nested ring c1, fixing base c2, horizontal pole c3, vibrations equipment c4, nested ring c1 inner wall welded fastening is in fixing base c2 left side, fixing base c2 right side horizontal pole c3 inlays fixedly in fixing base c2 left side, horizontal pole c3 right side activity block is in vibrations equipment c4 outer wall, horizontal pole c3 is equipped with two altogether, arranges in vibrations equipment c4 both ends relatively to thereby carry out the average nested ring c1 that drives with power and move.

Wherein, vibrations equipment c4 comprises eccentric ring d1, lantern ring d2, pivot d3, elevating system d4, the nested elevating system d4 right side that is fixed in of eccentric ring d1 inner wall, lantern ring d2 inner wall interference is fixed in pivot d3 outer wall, elevating system d4 left side is inlayed and is fixed in lantern ring d2 outer wall, its structure of eccentric ring d1 is oval structure, and the thickness of upper end is twice in the lower extreme, because of the upper end will carry out the contact collision, the increase of thickness can improve its structural strength to its structure makes, easier inflation to nested ring c1 inner wall after its centre of a circle skew.

The lifting mechanism d4 comprises a shell e1, a magnetic ring e2, a magnetic strip e3, a movable block e4 and a guide rod e5, the lower end of the magnetic ring e2 is fixedly embedded in the lower end of the inside of the shell e1, the right side of the magnetic strip e3 is fixedly arranged on the outer wall of the left side of the movable block e4 through buckles, the outer wall of the right lower end of the movable block e4 is fixedly welded on the upper left end of the guide rod e5, the outer wall of the guide rod e5 is completely assembled on the inner wall of the shell e1, the guide rod e5 is of a V-shaped structure, and when the left side of the guide rod e5 descends through.

The following examples are set forth: when static electricity is attached to the surface of equipment and the woven cloth can be adsorbed, the woven cloth cannot fall off when being transported to the tail end of a stroke due to the static electricity adsorption, in order to avoid the situation, the static electricity is conducted to the fixed seat c2 through the electrification of the nesting ring c1 and is input into the vibration equipment c4 through the fixed seat c2, after the vibration equipment c4 is electrified, the static current enters the lifting mechanism d4 through the eccentric ring d1, the magnetic ring e2 arranged inside the lifting mechanism d4 when the lifting mechanism d4 is subjected to the circulation of the static electricity adsorbs the static current through the magnetic field of the lifting mechanism d2, so that the static current is adsorbed to the coil attached to the surface of the magnetic ring e2, the magnetic force is generated through the guidance of the coil and is matched with the magnetic force of the magnetic ring e2, the magnetic force of the magnetic ring e2 is enhanced, the magnetic force of the magnetic strip e3 is adsorbed with high strength through the increase of the magnetic force, so that the magnetic strip, the left side of the guide rod e5 is pulled to descend and the right side of the guide rod e5 is tilted in the descending process of the movable block e4, the eccentric ring d1 is driven to ascend by tilting the right side of the guide rod e5, the circular position of the eccentric ring d1 can be changed by the ascending of the eccentric ring d1, the eccentric ring d1 is driven by the rotation of the rotating shaft d3 to rotate the eccentric ring d1 and expand the inside of the nested ring c1, the nested ring c1 vibrates, and the textile cloth reaching the stroke is vibrated through the vibration.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.