CN214736334U - Roving frame guide frame for textile production and processing - Google Patents

Abstract

The utility model discloses a fly frame guide bar frame is used in textile production processing relates to textile production technical field. The utility model discloses a first conducting bar frame, unable adjustment base, fibre sliver can, conducting bar roller and conducting bar loudspeaker, unable adjustment base top front end is fixed with five fibre sliver cans, the first conducting bar frame of unable adjustment base top fixedly connected with at fibre sliver can rear, the unable adjustment base top fixedly connected with second conducting bar frame at first conducting bar frame rear, first conducting bar frame internal rotation is connected with the conducting bar roller, second conducting bar frame internal rotation is connected with the conducting bar loudspeaker. The utility model solves the problem that the number of the guided fiber strips cannot be changed by the guide bar frame of the roving machine for the existing textile production and processing, so that the roving machine cannot twist with various numbers of the guided fiber strips by arranging the fixed base, the fiber sliver can, the nozzle and the first guide bar frame; the friction damage condition exists at the place where the fiber strips touch, which causes the problem that the quality of the roving twisted by the roving machine is not good.

Description

Roving frame guide frame for textile production and processing

Technical Field

The utility model belongs to the technical field of textile production, especially, relate to a fly frame guide frame is used in textile production processing.

Background

The roving frame is a spinning machine for making fiber slivers into roving, mainly plays a role in drafting and twisting, and winds the roving into a certain package so as to meet the processing requirements of the spinning frame, and is divided into a flyer roving frame and a twist roving frame according to the form of a twisting mechanism. The flyer roving frame rotates by means of flyer to continuously apply twist to the sliver so as to produce twisted roving. The twist roving frame clamps and twists the yarn by a pair of twist leather plates, and forms a false twist with alternate forward and reverse directions on the yarn to produce untwisted roving. The flyer roving frame and twist roving frame can be divided into a first channel, a second channel and a single-way roving frame. The feeding form, roving package and spindle number of the machine of various roving frames are different, but the structure and the function of the machine are approximately the same, a sliver guide frame is needed to guide fiber slivers into the roving frame before the roving frame works, but the following defects still exist in the practical use of the roving frame:

1. the number of the guided fiber strips cannot be changed by a guide frame of the existing roving frame for textile production and processing, so that the roving frame cannot carry out twisting work with various numbers of the guided fiber strips;

2. the roving frame for the existing textile production and processing has the condition of friction damage at the place where a fiber strip is touched, so that the roving quality twisted by the roving frame is not good.

Therefore, the conventional roving frame for textile production and processing cannot meet the requirements in practical use, so that an improved technology is urgently needed in the market to solve the problems.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a roving frame for textile production and processing, which solves the problem that the number of guided fiber strips cannot be changed by the prior roving frame for textile production and processing through arranging a fixed base, a fiber sliver can, a nozzle and a first guide frame, so that the roving frame cannot twist with various numbers of guided fiber strips; the roving frame for textile production and processing has the problem that the roving quality twisted by the roving frame is not feasible due to the friction damage condition at the place where the fiber strips touch.

In order to solve the technical problem, the utility model discloses a realize through following technical scheme:

the utility model relates to a fly frame guide for textile production processing, including first guide, unable adjustment base, fibre sliver can, guide roller and guide loudspeaker, unable adjustment base top front end is fixed with five fibre sliver cans, the first guide of unable adjustment base top fixedly connected with at fibre sliver can rear, first guide upper portion is provided with the recess, and the recess bottom is provided with ascending fillet, the unable adjustment base top fixedly connected with second guide at first guide rear, second guide upper portion is provided with the recess, first guide internal rotation is connected with the guide roller, and the guide roller rotates and connects in the recess on first guide upper portion, second guide internal rotation is connected with guide loudspeaker, and guide loudspeaker rotate and connect in the recess on second guide upper portion.

Further, first pivot hole is provided with at first conducting bar frame inboard both ends, and the internal rotation in first pivot hole is connected with the roller pivot on the conducting bar roller, second conducting bar frame inboard both ends are provided with the second pivot hole, and the downthehole internal rotation of second pivot is connected with the loudspeaker pivot on the conducting bar loudspeaker.

Furthermore, five barrel grooves are fixedly connected to the front end above the fixed base, and five fiber barrels are fixed in the five barrel grooves respectively.

Further, a barrel opening is fixed above the fiber sliver can, a round angle is arranged above the barrel opening, threads are arranged on the outer wall of the barrel opening, a barrel cover is rotatably connected to the upper portion of the fiber sliver can outside the barrel opening, and threads are arranged on the inner wall of the barrel cover.

Further, the two ends of the conducting bar roller are fixedly connected with roller rotating shafts, the two ends of the roller rotating shafts are rotatably connected into first rotating shaft holes in the first conducting bar frame, one end of each roller rotating shaft is rotatably connected with a first transmission belt inside the first conducting bar frame, the inner ring of each first transmission belt is provided with a gear structure, the upper part and the lower part of each first transmission belt are respectively connected with a first gear and a first motor through gears, the lower part of each first transmission belt is rotatably connected with a first gear, the inside of each first gear is rotatably connected with a first motor output shaft, the outside of each first transmission belt is rotatably connected with the corresponding first transmission belt, each first gear is internally rotatably connected with a first motor, and the first motor output shaft is rotatably connected with the corresponding first gear.

Furthermore, the two ends of the guide bar horn are fixedly connected with horn rotating shafts, the two ends of the horn rotating shafts are connected in second rotating shaft holes in a second guide bar frame in a rotating mode, one end of each horn rotating shaft is connected with a second transmission belt in a rotating mode and located inside the second guide bar frame, gear structures are arranged on inner rings of the second transmission belts, the upper portion and the lower portion of each horn rotating shaft are connected with gears between one end of each horn rotating shaft and the corresponding second gear respectively, the lower portion of each second transmission belt is connected with the corresponding second gear in a rotating mode, the inner portion of each second gear is connected with a second motor output shaft in a rotating mode, the outer portion of each second transmission belt is connected with the corresponding second transmission belt in a rotating mode, and the second motor output shaft is connected with the corresponding second gear in a rotating mode.

The utility model discloses following beneficial effect has:

1. the utility model discloses a set up unable adjustment base, a sliver can groove and a fiber can, solved current roving frame guide for textile production processing and can not change the track number of deriving the ribbon to the problem of the twisting work of multiple track number can't be carried out to the roving frame, the utility model discloses five sliver cans of unable adjustment base top are fixed with five fiber cans respectively in the inslot, and five fiber cans can simultaneous working, and a plurality of fiber cans make the device can carry out multichannel spinning, also can only use wherein part fiber can carry out the spinning that needs the track number.

2. The utility model discloses a set up fibre sliver can, nozzle and first gib block, solved current roving frame for textile production processing and had the friction damage condition in the place that the fibre strip touched, lead to the roving quality problem that the roving machine twisting came out, the utility model discloses during operation, the fibre strip derives fibre sliver can from the nozzle, and the nozzle top is provided with the fillet, and the friction damage with the nozzle when preventing that the fibre strip from deriving fibre sliver can, and first gib block upper portion is provided with the recess, and the recess bottom is provided with ascending fillet, makes the device at the during operation, and the fibre strip is not damaged by its friction through first gib block when following fibre sliver can direction gib roller.

Of course, it is not necessary for any particular product to achieve all of the above-described advantages at the same time.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic structural view of the present invention;

fig. 2 is a schematic structural view of a first guide bar frame and a second guide bar frame of the present invention;

fig. 3 is a schematic structural view of the fixing base of the present invention;

FIG. 4 is a schematic structural view of the fiber can of the present invention;

FIG. 5 is a schematic structural view of the conducting bar roller of the present invention;

fig. 6 is a schematic structural view of the conducting bar horn of the present invention.

In the drawings, the components represented by the respective reference numerals are listed below:

100. a first guide bar frame; 101. a first spindle hole; 200. a second guide bar frame; 201. a second spindle hole; 300. a fixed base; 301. a barrel groove; 400. a fiber sliver can; 401. a cylinder mouth; 402. a cylinder cover; 500. a sliver roller; 501. a roller rotating shaft; 502. a first drive belt; 503. a first gear; 504. a first motor; 600. a conducting bar horn; 601. a horn rotary shaft; 602. a second belt; 603. a second gear; 604. a second motor.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

Referring to fig. 1-6, the present invention relates to a roving frame for textile production and processing, which comprises a first sliver frame 100, a fixing base 300, fiber sliver cans 400, sliver rollers 500 and a sliver trumpet 600, wherein five fiber sliver cans 400 are fixed at the front end of the upper part of the fixing base 300, the five fiber sliver cans 400 can work simultaneously, a plurality of fiber sliver cans 400 can make the device perform multi-channel spinning, or only part of the fiber sliver cans 400 can be used for spinning with required channel number, the first sliver frame 100 is fixedly connected with the upper part of the fixing base 300 at the rear part of the fiber sliver cans 400, the upper part of the first sliver frame 100 is provided with a groove, the bottom end of the groove is provided with an upward fillet, so that when the device works, the fiber sliver can be guided to the sliver rollers 500 from the fiber sliver cans 400 through the first sliver frame 100 without being damaged by friction, the second sliver frame 200 is fixedly connected with the upper part of the fixing base 300 at the rear part of the first sliver frame 100, second guide frame 200 upper portion is provided with the recess, first guide frame 100 internal rotation is connected with guide roller 500, guide roller 500 rotates to be connected in the recess on first guide frame 100 upper portion, its effect is for deriving the ribbon in fiber barrel 400, and carry the ribbon, second guide frame 200 internal rotation is connected with guide loudspeaker 600, guide loudspeaker 600 rotates to be connected in the recess on second guide frame 200 upper portion, guide loudspeaker 600 plays the effect of bunching to the ribbon, carry the roving machine twisting with multichannel ribbon collection as one, guide loudspeaker 600 does the wearing and tearing that traverse motion reduction ribbon.

As shown in fig. 1 and 2, first pivot holes 101 are provided at two ends of the inner side of the first guide bar frame 100, roller pivots 501 on the guide bar roller 500 are rotatably connected to the first pivot holes 101, the first guide bar frame 100 is rotatably connected to the guide bar roller 500 through the first pivot holes 101, second pivot holes 201 are provided at two ends of the inner side of the second guide bar frame 200, horn pivots 601 on the guide bar horns 600 are rotatably connected to the second pivot holes 201, and the second guide bar frame 200 is rotatably connected to the guide bar horns 600 through the second pivot holes 201.

As shown in fig. 1 and 3, five can slots 301 are fixedly connected to the front end above the fixing base 300, five fiber cans 400 are respectively fixed in the five can slots 301, and the fixing base 300 fixes the fiber cans 400 above the fixing base through the can slots 301.

Wherein as shown in fig. 1, 4, a barrel opening 401 is fixed above a sliver can 400, when the device works, a sliver is led out of the sliver can 400 from the barrel opening 401, a round angle is arranged above the barrel opening 401, the sliver can 400 is prevented from being damaged by friction with the barrel opening 401 when being led out, a thread is arranged on the outer wall of the barrel opening 401, the barrel opening 401 is rotatably connected with a barrel cover 402 through the thread, a barrel cover 402 is rotatably connected above the sliver can 400 outside the barrel opening 401, a thread is arranged on the inner wall of the barrel cover 402, the inner wall of the barrel cover is rotatably connected with the thread on the outer wall of the barrel opening 401 through the thread on the inner wall, so that the barrel cover 402 is rotatably connected to the sliver can 400, and when the device does not work, the closed sliver can 400 is covered by the barrel cover 402.

As shown in fig. 1 and 5, two ends of a conducting bar roller 500 are fixedly connected with roller rotating shafts 501, two ends of the roller rotating shafts 501 are rotatably connected in first rotating shaft holes 101 on a first conducting bar frame 100, the conducting bar roller 500 is rotatably connected with the first conducting bar frame 100 through the roller rotating shafts 501, the roller rotating shafts 501 rotate to drive the conducting bar roller 500 to rotate, one end of the roller rotating shafts 501 is rotatably connected with a first driving belt 502 positioned inside the first conducting bar frame 100, the inner ring of the first driving belt 502 is provided with a gear structure, the upper part and the lower part are respectively in gear connection with one end of the roller rotating shafts 501 and a first gear 503, the first driving belt 502 moves to drive the roller rotating shafts 501 to rotate, the lower part of the first driving belt 502 is rotatably connected with a first gear 503, the inner part of the first gear 503 is rotatably connected with an output shaft of a first motor 504, the outer part is rotatably connected with the first driving belt 502, the first gear 503 rotates to drive the first driving belt 502 to move, the first gear 503 is used for transmitting the driving force of the first motor 504 to the first transmission belt 502, the first gear 503 is connected with the first motor 504 in a rotating way, the output shaft of the first motor 504 is connected with the first gear 503 in a rotating way, and the first motor 504 drives the first gear 503 to rotate.

As shown in fig. 1 and 6, the two ends of the conductive bar speaker 600 are fixedly connected with speaker rotating shafts 601, the two ends of the speaker rotating shafts 601 are rotatably connected to the second rotating shaft holes 201 on the second conductive bar frame 200, the conductive bar speaker 600 is rotatably connected to the second conductive bar frame 200 through the speaker rotating shafts 601, the speaker rotating shafts 601 are rotated reciprocally to drive the conductive bar speaker 600 to perform reciprocating rotation with slight swinging, one end of the speaker rotating shafts 601 is rotatably connected with a second transmission belt 602 located inside the second conductive bar frame 200, the inner ring of the second transmission belt 602 is provided with a gear structure, the upper and lower ends of the second transmission belt 602 are respectively connected with one end of the speaker rotating shafts 601 and a second gear 603 through gears, the second transmission belt 602 is moved to drive the speaker rotating shafts 601 to perform reciprocating rotation, the lower portion of the second transmission belt 602 is rotatably connected with a second gear 603, the inside of the second gear 603 is rotatably connected with an output shaft of a second motor 604, the outside of the second transmission belt 602, the second gear 603 is rotated to drive the second transmission belt 602 to perform reciprocating movement, the second gear 603 is used for transmitting the driving force of the second motor 604 to the second transmission belt 602, the second gear 603 is rotatably connected with the second motor 604, the output shaft of the second motor 604 is rotatably connected with the second gear 603, and the second motor 604 drives the second gear 603 to rotate back and forth.

One specific application of this embodiment is: the utility model relates to a roving frame for textile production and processing, five fiber sliver cans 400 are respectively fixed in five can grooves 301 above a fixed base 300, a can cover 402 covers the closed fiber sliver can 400 when the device does not work, when the device works, the can cover 402 is rotated to open, a fiber sliver is led out of the fiber sliver can 400 from a can opening 401, a round angle is arranged above the can opening 401 to prevent the fiber sliver from being damaged by friction with the can opening 401 when being led out of the fiber sliver can 400, a first motor 504 drives a first gear 503 to rotate, the first gear 503 drives a first transmission belt 502 to move, the first transmission belt 502 drives a roller rotating shaft 501 to rotate, the roller rotating shaft 501 drives a sliver roller 500 to rotate, the sliver roller 500 leads out the fiber sliver in the fiber sliver can 400 and conveys the fiber sliver, a second motor 604 drives a second gear 603 to do reciprocating rotation, the second gear 603 drives the second transmission belt 602 to do reciprocating motion, the second driving belt 602 moves to drive the horn rotating shaft 601 to rotate in a reciprocating manner, the horn rotating shaft 601 rotates in a reciprocating manner to drive the guide bar horn 600 to rotate in a reciprocating manner in a slight swinging manner, the guide bar horn 600 performs a bundling effect on the fiber strips, and a plurality of fiber strips are collected into one channel to be conveyed to the roving machine for twisting.

The above is only the preferred embodiment of the present invention, and the present invention is not limited thereto, any technical solutions recorded in the foregoing embodiments are modified, and some technical features thereof are replaced with equivalent ones, and any modification, equivalent replacement, and improvement made thereby all belong to the protection scope of the present invention.

Claims (6)

1. The utility model provides a roving frame is used in textile production processing, includes first sliver frame (100), unable adjustment base (300), fiber sliver can (400), sliver roller (500) and sliver loudspeaker (600), its characterized in that: the utility model discloses a fiber sliver guide roller, including unable adjustment base (300), unable adjustment base (300) top front end is fixed with five fiber sliver cans (400), unable adjustment base (300) top fixedly connected with first conducting bar frame (100) at fiber sliver can (400) rear, unable adjustment base (300) top fixedly connected with second conducting bar frame (200) at first conducting bar frame (100) rear, first conducting bar frame (100) internal rotation is connected with conducting bar roller (500), second conducting bar frame (200) internal rotation is connected with conducting bar loudspeaker (600).

2. The roving frame for the textile production and processing according to claim 1, wherein a first rotating shaft hole (101) is formed in each of two ends of the inner side of the first sliver frame (100), and a second rotating shaft hole (201) is formed in each of two ends of the inner side of the second sliver frame (200).

3. The roving frame for the textile production and processing as claimed in claim 1, wherein five bobbin grooves (301) are fixedly connected to the front end above the fixed base (300).

4. The roving frame for the textile production and processing as claimed in claim 1, wherein a bobbin opening (401) is fixed above the sliver can (400), and a bobbin cover (402) is rotatably connected above the sliver can (400) outside the bobbin opening (401).

5. The roving frame for the textile production and processing according to claim 1, wherein roller rotating shafts (501) are fixedly connected to two ends of the sliver guide roller (500), a first driving belt (502) is rotatably connected to one end of each roller rotating shaft (501) and located inside the first sliver guide frame (100), a first gear (503) is rotatably connected to the lower portion of each first driving belt (502), and the first gear (503) is rotatably connected with a first motor (504).

6. The roving frame for the textile production and processing according to claim 1, wherein a horn rotating shaft (601) is fixedly connected to two ends of the horn (600), a second transmission belt (602) is rotatably connected to one end of the horn rotating shaft (601) and located inside the second guide frame (200), a second gear (603) is rotatably connected to the lower portion of the second transmission belt (602), and the second gear (603) is rotatably connected with a second motor (604).

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