CN210765740U - Novel low-fork glove knitting machine - Google Patents

Abstract

The utility model relates to the technical field of glove knitting machines, in particular to a novel low-fork glove knitting machine, which comprises a low-fork scissor transmission mechanism which is added on the basis of the prior equipment, and a new needle selecting mechanism and a fork knife component are designed; the needle selection mechanism sequentially comprises a ring finger needle selection area, a middle finger needle selection area, a forefinger needle selection area, a three-finger palm needle selection area, a little finger needle selection area, a four-finger palm needle selection area, a thumb needle selection area, a five-finger palm needle selection area and a rib top needle selection area from top to bottom, and a shared area is arranged between the three-finger palm needle selection area and the little finger needle selection area; the fork knife component is provided with a left tensioning part and a right tensioning part; the advantages are that: a shared area is arranged between the three-finger palm needle selecting area and the little finger needle selecting area, so that the same tissue as the rest of fingers can be arranged between the three-finger palm and the little finger; the neutral position of the right tensioning part realizes the thread hooking action of the lower hook knife, and high-standard low-fork finger separation is realized; the three-finger palm is tensioned through the right tensioning part, and the knitting of the little finger is realized.

Description

Novel low-fork glove knitting machine

Technical Field

The utility model relates to a glove machine technical field especially relates to a novel low fork gloves braider.

Background

The general process of processing low-pronged gloves by a common computer knitting glove machine comprises the following steps: under the coordination of the knitting mechanism and the needle selection mechanism, a little finger, a ring finger, a middle finger and a forefinger are firstly knitted, then three palms of fingers, four palms of fingers and a thumb are knitted, and then five palms of fingers and a rib opening are knitted, wherein after the little finger, the ring finger, the middle finger and the four palms of fingers are knitted, the forked cutter transmission mechanism and the scissors mechanism are matched to act to finish glove finger separation, because three palms of fingers are knitted after the forefinger is knitted, the needle selection mechanism cannot have a shared area between a little finger needle selection area and a three palms of fingers from the aspect of the knitting principle, the gaps between the little finger and the three palms of fingers are large in the knitted low-pronged glove, the force of mutual pulling is insufficient, and when the low-pronged glove is used, the low-pronged glove is easy to damage at the fingers, and the service life and the product added value of the low-pronged glove are influenced.

Along with the progress of science and technology and the development of society, the requirements of people on low-pronged gloves are higher and higher, if a device capable of producing the novel low-pronged gloves can be developed, and the organization of the novel low-pronged gloves at the positions of the little fingers and the three-finger palm fingers is the same as that of the rest fingers, the novel low-pronged gloves have a promoting effect undoubtedly on the glove machine industry and have popularization significance.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a novel low fork gloves braider for improve the quality of weaving of low fork gloves.

In order to achieve the above purpose, the technical solution of the present invention is as follows:

a novel low-fork glove knitting machine comprises a frame, wherein a knitting mechanism, a needle plate, a needle selection mechanism, a fork blade control mechanism and a scissors control mechanism are arranged on the frame, a fork blade assembly is arranged on the fork blade control mechanism, a scissors mechanism is arranged on the scissors control mechanism, a low-fork scissors transmission mechanism is also arranged on the frame, and the low-fork scissors transmission mechanism is positioned below the fork blade assembly; the needle selection mechanism sequentially comprises a ring finger needle selection area, a middle finger needle selection area, a forefinger needle selection area, a three-finger palm needle selection area, a little finger needle selection area, a four-finger palm needle selection area, a thumb needle selection area, a five-finger palm needle selection area and a rib top needle selection area from top to bottom according to the unfolding, wherein a shared area is arranged between the three-finger palm needle selection area and the little finger needle selection area; the fork knife assembly comprises a front new fork knife and a rear new fork knife, a left hook portion and a right hook portion are arranged on the front new fork knife and the rear new fork knife relatively, the left hook portion of the front new fork knife and the left hook portion of the rear new fork knife are arranged relatively and form a left tensioning portion, and the right hook portion of the front new fork knife and the right hook portion of the rear new fork knife are arranged relatively and form a right tensioning portion.

Further, the low-fork scissors transmission mechanism comprises a scissors seat, a motor seat, a push rod and a sliding plate which are mutually connected, wherein the motor seat is connected with a motor, a rotating part of the motor is connected with a connecting block, the scissors seat is provided with a rotating shaft and is connected with a lower hook knife in a sliding manner, the upper end of the rotating shaft is matched with a scissors wire clamping device arranged on the scissors seat, and the lower end of the rotating shaft is connected with a rotating block; the two ends of the push rod are respectively hinged with the sliding plate and the connecting block, the sliding plate comprises a plate I and a plate II which are perpendicular to each other, a vertically arranged long hole I is formed in the plate I, the long hole I is linear and is penetrated with a positioning screw connected with the scissor seat, a notch is formed in the lower hook cutter, and a protrusion located in the notch is formed in the plate I; and a second long hole is formed in the second plate, the second long hole sequentially comprises a long straight track section, an inclined track section and a short straight track section from bottom to top, and a small shaft inserted into the second long hole is arranged on the rotating block.

Furthermore, a vertically-arranged flat chute is formed in the scissor seat, the lower hook knife is located in the flat chute, a convex portion protruding out of the flat chute is formed in the lower hook knife, and the notch is formed in the convex portion.

Furthermore, the two ends of the scissor seat, which are positioned on the flat sliding groove, are respectively provided with an upper cover plate and a lower cover plate which are opposite to the convex part.

Furthermore, a pressure spring is connected between the rotating shaft and the rotating block.

Furthermore, an inductive switch corresponding to the connecting block is fixed on the motor base.

The utility model has the advantages that:

1. by designing a novel needle selecting mechanism and arranging a common area between the three-finger palm needle selecting area and the little finger needle selecting area, the glove knitting machine can knit the same tissue with the rest fingers between the three-finger palm and the little finger;

2. the scissors control mechanism and the scissors mechanism are used for the finger-separating operation between the ring finger and the middle finger, between the middle finger and the index finger, and between the four palms of the fingers and the thumb, and the low-fork scissors transmission mechanism is used for the finger-separating operation between the three palms of the fingers and the little finger; meanwhile, the low-fork scissors transmission mechanism simultaneously controls the lower hook cutter and the scissors wire clamping device through the sliding plate, so that the structure is simplified, the cost is reduced, and the long hole I and the long hole II are adopted for direct transmission, so that the force transmission is more direct, and the improvement of the precision is facilitated;

3. the left side and the right side of the front fork knife and the rear fork knife are provided with tensioning parts with symmetrical shapes, when the palm of the three fingers and the little finger are separated,

the neutral position of the right tensioning part realizes the thread hooking action of the lower hook knife, and high-standard low-fork finger separation is realized; the three-finger palm is tensioned through the right tensioning part, and the knitting of the little finger is realized.

Drawings

Fig. 1 is a schematic configuration diagram of the present invention in an embodiment;

FIG. 2 is a schematic plan view of a knitted low-crotch glove according to an embodiment of the present invention;

FIG. 3 is a schematic view showing the needle selecting mechanism in the embodiment;

FIG. 4 is a schematic view of a prior art arrangement of a dropout control mechanism and dropout assembly;

FIG. 5 is a schematic view showing the construction of the fork-knife assembly in the embodiment;

FIG. 6 is a schematic diagram showing the construction of a transmission mechanism of the low-fork scissors according to the embodiment;

fig. 7 is a schematic view of the configuration of the scissor mount of fig. 6;

FIG. 8 is a schematic view showing the construction of the slide plate of FIG. 6;

FIG. 9 is an assembled view of FIG. 6;

FIG. 10 is a schematic view of the fork assembly and the scissors mechanism of the present embodiment showing the hook lines when the fingers are separated;

FIG. 11 is a schematic view of the low-dropout scissor drive mechanism and the fork assembly for hooking when the fingers are separated in the embodiment;

FIG. 12 is a schematic view of the low-fork scissor transmission mechanism according to the embodiment;

description of the reference symbols

1 machine frame, 2 weaving mechanism, 3 needle plate, 4 fork knife control mechanism,

5 fork knife component, 51 front new fork knife, 52 rear new fork knife, 53 left hook part, 54 right hook part,

a scissors control mechanism 6, a scissors mechanism 7,

8 needle selection mechanisms, 81 ring finger needle selection areas, 82 middle finger needle selection areas, 83 forefinger needle selection areas, 84 three-fingered palm needle selection areas, 85 little finger needle selection areas, 86 four-fingered palm needle selection areas, 87 thumb needle selection areas, 88 five-fingered palm needle selection areas, 89 rib top needle selection areas, 81a ring finger, 82a middle finger, 83a forefinger, 84a three-fingered palm, 85a little finger, 86a four-fingered palm, 87a thumb, 88a five-fingered palm and 89a rib top,

9 low fork scissors drive mechanism, 91 motor cabinet, 92 scissors seat, 93 motor, 94 connecting block, 95 axis of rotation, 96 lower collude sword, 97 scissors trapping mechanism, 98 rotating block, 99 staff, 910 push rod, 911 sliding plate, 912 board one, 913 board two, 914 slot hole one, 915 slot hole two, 916 set screw, 917 protruding, 918 breach, 919 convex part, 920 long straight track section, 921 inclined track section, 922 short straight track section, 923 spout, 924 upper cover plate, 925 flat lower cover plate, 926 pressure spring, 927 inductive switch, 928 round pin axle, 929 push rod connecting piece, 930 upper breach, 931 lower breach, 932 shaft hole.

Detailed Description

The present invention will be described in further detail with reference to examples.

The embodiment provides a novel low-fork glove knitting machine, as shown in fig. 1, including frame 1, be equipped with knitting mechanism 2 on frame 1, faller 3, select needle mechanism 8, forked knife control mechanism 4 and scissors control mechanism 6, be equipped with forked knife subassembly 5 on the forked knife control mechanism 4, be equipped with scissors mechanism 7 on the scissors control mechanism 6, frame 1, knitting mechanism 2, faller 3, forked knife control mechanism 4, scissors control mechanism 6 and the relation of connection between each mechanism in this application are prior art, can specifically refer to the patent application with patent number CN201910508705.7, do not do too much here. In this embodiment, the frame 1 is further provided with a low-fork scissor transmission mechanism 9, and the low-fork scissor transmission mechanism 9 is located below the fork assembly 5; as shown in fig. 3, the needle selecting mechanism 8 includes, in order from top to bottom, a ring finger needle selecting area 81, a middle finger needle selecting area 82, an index finger needle selecting area 83, a three finger palm needle selecting area 84, a little finger needle selecting area 85, a four finger palm needle selecting area 86, a thumb needle selecting area 87, a five finger palm needle selecting area 88, and a rib top needle selecting area 89, and a common area is provided between the three finger palm needle selecting area 84 and the little finger needle selecting area 85.

As shown in fig. 4, a forking cutter control mechanism 4 in the prior art is provided, and a forking cutter assembly is fixed on the forking cutter control mechanism 4, but only one tensioning portion (corresponding to the left tensioning portion in this embodiment) is provided on the forking cutter assembly in the prior art, and after the needle selection mechanism 8 in this embodiment is adopted, the front forking cutter and the rear forking cutter in the prior art cannot complete the knitting of the novel low-forking glove. Therefore, as shown in fig. 5, the fork assembly 5 of the present embodiment includes a front new fork blade 51 and a rear new fork blade 52, the front new fork blade 51 and the rear new fork blade 52 are respectively provided with a left hook portion 53 and a right hook portion 54, the left hook portion 53 of the front new fork blade 51 and the left hook portion 53 of the rear new fork blade 52 are oppositely disposed and form a left tensioning portion, the right hook portion 54 of the front new fork blade 51 and the right hook portion 54 of the rear new fork blade 52 are oppositely disposed and form a right tensioning portion, and the design of the hook portions enables a neutral position to be formed between the two left hook portions 53 of the left tensioning portion and a neutral position to be formed between the two right hook portions 54 of the right tensioning portion. As shown in fig. 10 and 11, the hook knife on the scissors mechanism 7 (or the lower hook knife 96 on the low-fork scissors transmission mechanism 9) needs to go out of the neutral position to hook the thread, because: because the gap between the front and rear new fork blades 51 and 52 is too small after being installed, the hook blade cannot pass through the installation gap, and the neutral position is formed, so that the hook blade can conveniently enter and exit from the neutral position, and the wire hooking operation is realized.

As shown in fig. 6 to 9, the low-fork scissors transmission mechanism 9 in this embodiment includes a scissors base 92 and a motor base 91 that are connected to each other, the motor base 91 is connected to a motor 93, a rotating portion of the motor 93 is connected to a connecting block 94, the scissors base 92 is provided with a rotating shaft 95 and slidably connected to a lower hook knife 96, an upper end of the rotating shaft 95 is fitted with a scissors wire clamping device 97 mounted on the scissors base 92, and a lower end of the rotating shaft 95 is connected to a rotating block 98; the embodiment further comprises a push rod 910 and a sliding plate 911, wherein two ends of the push rod 910 are hinged to the sliding plate 911 and the connecting block 94 respectively, the lower end of the push rod 910 is connected with the connecting block 94 through a pin 928, and the upper end of the push rod 910 is connected with the lower end of the sliding plate 911 through a push rod connector 929. The sliding plate 911 comprises a first plate 912 and a second plate 913 which are perpendicular to each other, wherein a first vertically-arranged long hole 914 is formed in the first plate 912, the first long hole 914 is linear, a positioning screw 916 connected with the scissor seat 92 penetrates through the first long hole 914, and the positioning screw 916 is used for positioning the sliding plate 911 to ensure that the sliding plate 911 can move up and down linearly. A notch 918 is arranged on the lower hook cutter 96, and a protrusion 917 positioned in the notch 918 is arranged on the first plate 912; a second long hole 915 is formed in the second plate 913, the second long hole 915 sequentially comprises a long straight track section 920, an inclined track section 921 and a short straight track section 922 from bottom to top, and a small shaft 99 inserted into the second long hole 915 is arranged on the rotating block 98.

More specifically, a vertically arranged flat sliding groove 923 is formed in the scissors seat 92, the lower hook knife 96 is located in the flat sliding groove 923, a convex portion 919 protruding from the flat sliding groove 923 is formed in the lower hook knife 96, the notch 918 is formed in the convex portion 919, an upper cover plate 924 and a lower cover plate 925 opposite to the convex portion 919 are respectively arranged at two ends of the scissors seat 92 located in the flat sliding groove 923, and the upper cover plate 924 and the lower cover plate 925 are used for limiting the limit position of the lower hook knife 96 in vertical movement. As shown in fig. 7, an upper notch 930 and a lower notch 931 are formed on one side of the scissors seat 92 away from the flat sliding slot 923, the rotating block 98 is located in the lower notch 931, a shaft hole 932 is formed on a side wall of the upper notch 930 and the lower notch 931, a lower end of the rotating shaft 95 passes through the shaft hole 932 and enters the lower notch 931 and is connected with the rotating block 98, preferably, a pressure spring 926 is further disposed between the rotating shaft 95 and the rotating block 98, and the pressure spring 926 acts to push the scissors seat 92 upward, so that cutting edges of the fixed scissors and the movable scissors in the scissors wire clamping device 97 are always kept in close contact in the shearing process, and the shearing force is enhanced.

In this embodiment, an inductive switch 927 corresponding to the connection block 94 is further fixed on the motor base 91, and the inductive switch 927 controls the rotation of the motor 93 by sensing the position of the connection block 94.

The working principle of the low-fork scissor transmission mechanism 9 in the embodiment is as follows:

(1) the thread hooking action: the motor 93 rotates to drive the connecting block 94 and the push rod 910 to move, the push rod 910 pushes the sliding plate 911, so that the first long hole 914 of the sliding plate 911 moves upward along the axis of the positioning screw 916, meanwhile, the small shaft 99 on the rotating block 98 moves along the long straight track section 920 of the second long hole 915, and the protrusion 917 of the sliding plate 911 drives the lower hook knife 96 to move upward along the flat sliding groove 923 at the notch 918 of the lower hook knife 96 until the cutter head of the lower hook knife 96 can hook the yarn, as shown in fig. 11;

(2) thread trimming and clamping action: when the motor 93 rotates reversely, the push rod 910 pulls the sliding plate 911 to make the first long hole 914 of the sliding plate 911 move downward along the axis of the positioning screw 916, the small shaft 99 of the rotating block 98 initially moves along the long straight track section 920 of the second long hole 915, and then the cutter head of the lower hook cutter 96 hooks the yarn and moves downward until the yarn enters the scissors wire clamping device 97, at this time, the small shaft 99 of the rotating block 98 enters the oblique track section 921, and then the rotating shaft 95 drives the scissors wire clamping device 97 to start wire clamping and wire cutting, when the sensing switch 927 detects the connecting block 94, the sensing switch 927 sends a signal, the motor 93 stops rotating, and the scissors wire clamping device 97 finishes the wire clamping and wire cutting, as shown in fig. 12.

The production process of the glove knitting machine of the embodiment needs to go through the following steps:

(1) after the needle of the needle plate 3 needle groove is selected by the needle selecting mechanism 8, the knitting needle participates in the knitting along the triangle motion arranged on the knitting mechanism 2, according to the setting sequence of the needle selecting mechanism 8, the ring finger 81a is knitted first, correspondingly, the needle selecting mechanism 8 is in the ring finger needle selecting area 81;

(2) after the ring finger 81a is knitted, the scissors control mechanism 6 drives the scissors mechanism 7 to move, the fork blade control mechanism 4 controls the fork blade assembly 5 to move until neutral positions of the scissors mechanism 7 and the left tensioning portion both move to the positions of the ring finger 81a and the middle finger 82a, then the scissors mechanism 7 carries out finger separation on the ring finger 81a and the middle finger 82a, the finger separation process of the scissors mechanism 7 is shown in fig. 10, a hook blade of the scissors mechanism 7 penetrates out of the neutral position of the left tensioning portion, then the yarn is hooked and pulled downwards, and then the scissors mechanism 7 carries out yarn clamping and cutting actions;

(3) the fork blade control mechanism 4 drives the fork blade assembly 5 to move right until the left tensioning part tensions the ring finger 81a, then middle finger 82a knitting is carried out, and correspondingly, the needle selecting mechanism 8 is positioned in the middle finger selecting needle area 82;

(4) after the middle finger 82a is woven, the scissors control mechanism 6 drives the scissors mechanism 7 to move, the fork blade control mechanism 4 controls the fork blade assembly 5 to move until the neutral positions of the scissors mechanism 7 and the left tensioning part move to the positions where the middle finger 82a and the index finger 83a are separated, and then the scissors mechanism 7 separates the middle finger 82a and the index finger 83 a;

(5) the fork blade control mechanism 4 drives the fork blade assembly 5 to move right until the tensioning part on the left side tensions the middle finger 82a, then the index finger 83a is woven, then the three-fingered palm 84a is woven, and correspondingly, the needle selection mechanism 8 is respectively positioned in the index finger and the three-fingered palm needle selection areas 83 and 84;

(6) after the three finger palms 84a are knitted, the fork blade control mechanism 4 drives the fork blade assembly 5 to move right until the neutral position of the right tensioning part is positioned above the lower hook blade 96 of the low-fork scissor transmission mechanism 9, as shown in fig. 11 and 12, the low-fork scissor transmission mechanism 9 performs finger separation on the three finger palms 84a and the little finger 85a through the wire hooking action and the wire cutting and clamping action of the low-fork scissor transmission mechanism;

(7) the fork blade control mechanism 4 drives the fork blade component 5 to move left until the right tensioning part tensions the three finger palm 84a, then the little finger 85a is woven, then the four finger palm 86a is woven, and correspondingly, the needle selecting mechanism 8 is respectively positioned in the little finger and four finger palm needle selecting areas 85 and 86;

(8) after the four-finger palm 86a is woven, the scissors control mechanism 6 drives the scissors mechanism 7 to move, the fork blade control mechanism 4 drives the fork blade assembly 5 to move until neutral positions of the scissors mechanism 7 and the left tensioning part move to a finger separating position of the four-finger palm 86a and the thumb 87a, and the scissors mechanism 7 separates the four-finger palm 86a and the thumb 87 a;

(9) the forked cutter control mechanism 4 drives the forked cutter assembly 5 to move right until the left tensioning part tensions the four finger palms 86a, then the thumb 87a is woven, then the five finger palms 88a and the rib openings 89a are woven, correspondingly, the needle selection mechanism 8 is respectively positioned in the thumb, the five finger palms and the rib openings needle selection areas 87, 88 and 89, as shown in fig. 2, the plane schematic diagram of the novel low-forked glove after the weaving is finished.

The above embodiments are only used for explaining the concept of the invention, and not for limiting the protection of the invention, and any insubstantial modifications of the invention using this concept shall fall within the scope of the invention.

Claims (6)

1. The utility model provides a novel low fork gloves braider, includes the frame, is equipped with knitting mechanism, faller in the frame, selects needle mechanism, forked knife control mechanism and scissors control mechanism, is equipped with the forked knife subassembly on the forked knife control mechanism, is equipped with scissors mechanism, its characterized in that on the scissors control mechanism: the frame is also provided with a low-fork scissor transmission mechanism which is positioned below the fork assembly; the needle selection mechanism sequentially comprises a ring finger needle selection area, a middle finger needle selection area, a forefinger needle selection area, a three-finger palm needle selection area, a little finger needle selection area, a four-finger palm needle selection area, a thumb needle selection area, a five-finger palm needle selection area and a rib top needle selection area from top to bottom according to the unfolding, wherein a shared area is arranged between the three-finger palm needle selection area and the little finger needle selection area; the fork knife assembly comprises a front new fork knife and a rear new fork knife, a left hook portion and a right hook portion are arranged on the front new fork knife and the rear new fork knife relatively, the left hook portion of the front new fork knife and the left hook portion of the rear new fork knife are arranged relatively and form a left tensioning portion, and the right hook portion of the front new fork knife and the right hook portion of the rear new fork knife are arranged relatively and form a right tensioning portion.

2. The novel low-dropout glove knitting machine as claimed in claim 1, wherein: the low-fork scissors transmission mechanism comprises a scissors seat, a motor seat, a push rod and a sliding plate which are mutually connected, wherein the motor seat is connected with a motor, a rotating part of the motor is connected with a connecting block, the scissors seat is provided with a rotating shaft and is connected with a lower hook knife in a sliding way, the upper end of the rotating shaft is matched with a scissors wire clamping device arranged on the scissors seat, and the lower end of the rotating shaft is connected with a rotating block; the two ends of the push rod are respectively hinged with the sliding plate and the connecting block, the sliding plate comprises a plate I and a plate II which are perpendicular to each other, a vertically arranged long hole I is formed in the plate I, the long hole I is linear and is penetrated with a positioning screw connected with the scissor seat, a notch is formed in the lower hook cutter, and a protrusion located in the notch is formed in the plate I; and a second long hole is formed in the second plate, the second long hole sequentially comprises a long straight track section, an inclined track section and a short straight track section from bottom to top, and a small shaft inserted into the second long hole is arranged on the rotating block.

3. The novel low-dropout glove knitting machine as claimed in claim 2, wherein: the scissors seat is provided with a vertically-arranged flat chute, the lower hook knife is positioned in the flat chute, a convex part protruding out of the flat chute is arranged on the lower hook knife, and the notch is formed in the convex part.

4. The novel low-dropout glove knitting machine as claimed in claim 3, wherein: the two ends of the scissor seat, which are positioned on the flat sliding groove, are respectively provided with an upper cover plate and a lower cover plate which are opposite to the convex part.

5. The novel low-dropout glove knitting machine as claimed in claim 2, wherein: and a pressure spring is connected between the rotating shaft and the rotating block.

6. The novel low-dropout glove knitting machine as claimed in claim 2, wherein: and an inductive switch corresponding to the connecting block is fixed on the motor base.

Images