CN209892712U - Multi-mode fishing net braider motion - Google Patents
Multi-mode fishing net braider motion Download PDFInfo
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- CN209892712U CN209892712U CN201920179927.4U CN201920179927U CN209892712U CN 209892712 U CN209892712 U CN 209892712U CN 201920179927 U CN201920179927 U CN 201920179927U CN 209892712 U CN209892712 U CN 209892712U
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Abstract
The utility model provides a multi-mode fishing net braider motion, this mechanism relate to textile machinery technical field. The motion mechanism comprises a box body, a driving shaft, a driven shaft a, a driven shaft b, a driven shaft c, a driven shaft d, a driven shaft e and a driven shaft f, wherein the parts are respectively arranged on the box body; the driving shaft is connected with a driven shaft a through a gear transmission mechanism a, and the driven shaft a is connected with a driven shaft b through a gear transmission mechanism b; the driven shaft c, the driven shaft d, the driven shaft e and the driven shaft f are connected through three different connection schemes, so that three different weaving modes, namely a three-horizontal-one-twisting weaving mode, a horizontal-twisting weaving mode and a single-twisting weaving mode, are realized. The movement mechanism is high in transmission precision, small in size, simple in structure and convenient to disassemble, intermittent movement can be achieved by using the cam, movement stability is improved, different power outputs can be achieved, and therefore the weaving function of multiple modes is achieved.
Description
The technical field is as follows:
the utility model relates to a textile machinery technical field relates to a constitution mechanism of fishing net braider, especially relates to a multi-mode fishing net braider motion.
Background art:
the fishing net braiding machine motion mechanism is an important component mechanism of the fishing net braiding machine, and realizes the braiding function of the fishing net braiding machine through power output. The motion mechanism of the prior fishing net braiding machine adopts the traditional chain type or gear transmission, is generally positioned above the fishing net braiding machine, has lower transmission precision, realizes continuous motion, and has larger volume, complex structure and troublesome replacement. Meanwhile, the motion mechanism of the current fishing net braiding machine has single function, cannot generate different motion outputs according to production requirements, and has certain limitation. The existing fishing net knitting machine adopts a spring to perform return movement, and the stability is poor.
The utility model has the following contents:
in view of this, the utility model provides a multi-mode fishing net braider motion, its transmission precision is high, realizes intermittent type nature motion, and small, simple structure, dismantlement convenience, and can realize different power take off, realize the function of weaving of multiple mode, improve the stability of motion simultaneously.
Specifically, the utility model discloses a realize through following technical scheme:
a multi-mode fishing net braiding machine movement mechanism comprises a box body, a driving shaft, a driven shaft a, a driven shaft b, a driven shaft c, a driven shaft d, a driven shaft e and a driven shaft f, wherein the driving shaft, the driven shaft a, the driven shaft b, the driven shaft c, the driven shaft d, the driven shaft e and the driven shaft f are respectively installed on the box body; the driving shaft is connected with a driven shaft a through a gear transmission mechanism a, and the driven shaft a is connected with a driven shaft b through a gear transmission mechanism b; the driven shaft c, the driven shaft d, the driven shaft e and the driven shaft f are connected by adopting any one of the following three connection schemes:
firstly, the driven shaft b is connected with a driven shaft c through a gear transmission mechanism c, the driven shaft b is connected with a driven shaft f through a gear transmission mechanism d, the driven shaft c is connected with a driven shaft d through a swing mechanism a, and the driven shaft c is connected with a driven shaft e through a swing mechanism b so as to realize a three-strand and one-strand braiding mode;
secondly, the driven shaft b is connected with a driven shaft c through a gear transmission mechanism c to realize a flat-twisting weaving mode;
and thirdly, the driven shaft a is connected with a driven shaft f through a gear transmission mechanism e, and the driven shaft a is connected with a driven shaft c through a link mechanism so as to realize a single-twist weaving mode.
The gear transmission mechanism a comprises an input gear a and an output gear a; the input gear a is sleeved on the driving shaft and meshed with the output gear a sleeved on the driven shaft a, and the transmission ratio of the input gear a to the output gear a is 1: 2.
The gear transmission mechanism b comprises an input gear b and an output gear b; the input gear b is sleeved on the driven shaft a and meshed with the output gear b sleeved on the driven shaft b, and the transmission ratio of the input gear b to the output gear b is 1: 2.
The gear transmission mechanism c comprises an input gear c and an output gear c; the input gear c is sleeved on the driven shaft b and meshed with the output gear c sleeved on the driven shaft c, and the transmission ratio of the input gear c to the output gear c is 1: 1.5.
The gear transmission mechanism d comprises an input gear d and an output gear d; the input gear d is sleeved on the driven shaft b and meshed with the output gear d sleeved on the driven shaft f, and the transmission ratio of the input gear d to the output gear d is 1: 2.
The gear transmission mechanism e comprises an input gear e and an output gear d; the input gear e is sleeved on the driven shaft a and meshed with the output gear d sleeved on the driven shaft f, and the transmission ratio of the input gear e to the output gear d is 1: 3.
The connecting rod mechanism comprises a rocker arm f, a rocker arm e and a connecting rod; one end of the rocker arm f is sleeved on the driven shaft a, and the other end of the rocker arm f is connected with one end of the connecting rod; one end of the connecting rod is connected with the rocker arm f, and the other end of the connecting rod is connected with the rocker arm e; one end of the rocker arm e is sleeved on the driven shaft c, and the other end of the rocker arm e is connected with the connecting rod.
The swing mechanism a comprises a cam a, a cam b, a swing arm a and a swing arm b; one end of the swing arm a is sleeved on the driven shaft d, and the other end of the swing arm a is connected with the cam a; the cam a is sleeved on the driven shaft c; one end of the swing arm b is sleeved on the driven shaft d, and the other end of the swing arm b is connected with the cam b; the cam b is sleeved on the driven shaft c.
One end of the swing arm a connected with the cam a is provided with a roller a which is tangent with the outer contour of the cam a; one end of the swing arm b connected with the cam b is provided with a roller b which is tangent with the outline of the cam b.
The swing mechanism b comprises a cam c, a cam d, a swing arm c and a swing arm d; one end of the swing arm c is sleeved on the driven shaft e, and the other end of the swing arm c is connected with the cam c; the cam c is sleeved on the driven shaft c; one end of the swing arm d is sleeved on the driven shaft e, and the other end of the swing arm d is connected with the cam d; the cam d is sleeved on the driven shaft c.
One end of the swing arm c, which is connected with the cam c, is provided with a roller c which is tangent with the outer contour of the cam c; one end of the swing arm d, which is connected with the cam d, is provided with a roller d which is tangent with the outline of the cam d.
Compared with the prior art, the utility model discloses a beneficial effect that multi-mode fishing net braider motion has is: the multi-mode fishing net braiding machine motion mechanism utilizes a gear transmission mechanism and a connecting rod transmission mechanism to realize high-precision transmission; meanwhile, the purposes of small volume, simple structure and convenient disassembly of the mechanism can be achieved; the intermittent movement of the mechanism is realized by using the cam, so that the movement stability is ensured; through the combination of different transmission structures, different power outputs can be realized, and the weaving function of multiple modes is realized.
Drawings
FIG. 1 is a schematic view of the overall motion mechanism of the embodiment of the present invention;
fig. 2 is a schematic view of a three-strand and one-strand movement mechanism according to an embodiment of the present invention;
FIG. 3 is a schematic view of a horizontal twisting motion mechanism according to an embodiment of the present invention;
FIG. 4 is a schematic view of a single-twisting motion mechanism according to an embodiment of the present invention;
figure 5 is a cross-sectional view of embodiment a-a of the present invention;
figure 6 is a cross-sectional view of embodiment B-B of the present invention;
figure 7 is a cross-sectional view of embodiment C-C of the present invention;
figure 8 is a cross-sectional view of embodiment D-D of the present invention;
fig. 9 is a cross-sectional view of embodiment E-E of the present invention.
Wherein: 1. a box body; 2. a drive shaft; 21. an input gear a; 23. a gear transmission mechanism a; 3. a driven shaft a; 31. an output gear a; 32. an input gear b; 33. an input gear e; 34. a gear transmission mechanism b; 35. a link mechanism; 351. a connecting rod; 36. a rocker arm f; 38. a gear transmission mechanism e; 4. a driven shaft b; 41. an output gear b; 42. an input gear c; 43. an input gear d; 45. a gear transmission mechanism c; 48. a gear transmission mechanism d; 5. a driven shaft c; 51. an output gear c; 52. a cam a; 53. a cam b; 54. a cam c; 55. a cam d; 56. a swing mechanism a; 57. a swing mechanism b; 58. a rocker arm e; 6. a driven shaft d; 61. a swing arm a; 611. a roller a; 62. a swing arm b; 621. roller b, 7, driven shaft e; 71. a swing arm c; 711. a roller c; 72. a swing arm d; 721. a roller d; 8. a driven shaft f; 81. and an output gear d.
The specific implementation mode is as follows:
as shown in figure 1, the motion mechanism of the multi-mode fishing net braiding machine comprises a box body 1, a driving shaft 2, a driven shaft a3, a driven shaft b4, a driven shaft c5, a driven shaft d6, a driven shaft e7, a driven shaft f8, a gear transmission mechanism a23 and a gear transmission mechanism b 34; the driving shaft 2, the driven shaft a3, the driven shaft b4, the driven shaft c5, the driven shaft d6, the driven shaft e7, the driven shaft f8, the gear transmission mechanism a23 and the gear transmission mechanism b34 are respectively arranged on the box body 1. The driving shaft 2 is connected with a driven shaft a3 through a gear transmission mechanism a 23; the output shaft a3 is connected with the output shaft b4 through a gear transmission mechanism b 34.
The gear train a23 includes an input gear a21 and an output gear a 31. The input gear a21 is sleeved on the driving shaft 2 and is meshed with the output gear a31 sleeved on the driven shaft a3, and the transmission ratio of the input gear a21 to the output gear a3 is 1: 2.
The gear transmission b34 includes an input gear b32 and an output gear b 41. The input gear b32 is sleeved on the driven shaft a3 and meshed with the output gear b41 sleeved on the driven shaft b4, and the transmission ratio of the input gear b32 to the output gear b41 is 1: 2.
The movement mechanism of the multi-mode fishing net braiding machine forms three movement mechanisms through the movement and the disassembly of related components, and the three movement mechanisms are respectively: the device comprises a three-dimensional and one-dimensional twisting movement mechanism, a three-dimensional and one-dimensional twisting movement mechanism and a single-dimensional twisting movement mechanism; thus, three weaving modes are realized, which are respectively as follows: three-flat-one-strand braiding mode, flat-strand braiding mode, single-strand braiding mode.
As shown in fig. 2, the three-strand and one-strand movement mechanism includes a housing 1, a driving shaft 2, a driven shaft a3, a driven shaft b4, a driven shaft c5, a driven shaft d6, a driven shaft e7, a driven shaft f8, a gear transmission mechanism a23, a gear transmission mechanism b34, a gear transmission mechanism c45, a gear transmission mechanism d48, a swinging mechanism a56, and a swinging mechanism b57, wherein the driving shaft 2, the driven shaft a3, the driven shaft b4, the driven shaft c5, the driven shaft d6, the driven shaft e7, the driven shaft f8, the gear transmission mechanism a23, the gear transmission mechanism b34, the gear transmission mechanism c45, the gear transmission mechanism d48, the swinging mechanism a56, and the swinging mechanism b57 are respectively mounted on the housing 1. The driving shaft 2 is connected with a driven shaft a3 through a gear transmission mechanism a 23; the driven shaft a3 is connected with a driven shaft b4 through a gear transmission mechanism b34, and the driven shaft b4 is connected with a driven shaft c5 through a gear transmission mechanism c 45; the driven shaft b4 is connected with the driven shaft f8 through a gear transmission mechanism d 48; the driven shaft c5 is connected with a driven shaft d6 through a swinging mechanism a 56; the driven shaft c5 is connected to the driven shaft e7 via a swing mechanism b 57.
The gear train c45 includes an input gear c42 and an output gear c 51. The input gear c42 is sleeved on the driven shaft b4 and is meshed with the output gear c51 sleeved on the driven shaft c5, and the transmission ratio of the input gear c42 to the output gear c51 is 1: 1.5.
The gear transmission mechanism d48 comprises an input gear d43 and an output gear d 81; the input gear d43 is sleeved on the driven shaft b4 and is meshed with the output gear d81 sleeved on the driven shaft f8, and the transmission ratio of the input gear d43 to the output gear d81 is 1: 2.
As shown in fig. 5 and 6, the swing mechanism a56 includes a cam a52, a cam b53, a swing arm a61, and a swing arm b 62; one end of the swing arm a61 is sleeved on the driven shaft d6, and the other end of the swing arm a61 is connected with the cam a 52; the cam a52 is sleeved on the driven shaft c 5; one end of the swing arm b62 is sleeved on the driven shaft d6, and the other end of the swing arm b62 is connected with the cam b 53; the cam b53 is sleeved on the driven shaft c 5.
One end of the swing arm a61, which is connected with the cam a52, is provided with a roller a611 which is tangent with the outer contour of the cam a 52; one end of the swing arm b62 connected with the cam b53 is provided with a roller b621 which is tangent with the outer contour of the cam b 53.
As shown in fig. 7 and 8, the swing mechanism b57 includes a cam c54, a cam d55, a swing arm c71 and a swing arm d 72; one end of the swing arm c71 is sleeved on the driven shaft e7, and the other end of the swing arm c71 is connected with the cam c 54; the cam c54 is sleeved on the driven shaft c 5; one end of the swing arm d72 is sleeved on the driven shaft e7, and the other end of the swing arm d72 is connected with the cam d 55; the cam d55 is sleeved on the driven shaft c 5.
One end of the swing arm c71, which is connected with the cam c54, is provided with a roller c711, which is tangent to the outer contour of the cam c 54; one end of the swing arm d72 connected with the cam d55 is provided with a roller d721 which is tangent with the outer contour of the cam d 55.
The kinetic energy of the three-strand and one-strand movement mechanism is input from the driving shaft 2, the driven shaft a3 is driven by the gear transmission mechanism a23, and the kinetic energy is transmitted to the driven shaft a3 and then is output in five paths: the first route is output by a driven shaft a 3; the second path drives the driven shaft b4 through the gear transmission mechanism b34, and is finally output by the driven shaft b4; the third path drives the driven shaft b4 through the gear transmission mechanism b34, drives the driven shaft f8 through the gear transmission mechanism d48 and finally is output by the driven shaft f 8; in the fourth path, the driven shaft b4 is driven by the gear transmission mechanism b34, the driven shaft c5 is driven by the gear transmission mechanism c45, the driven shaft d6 is driven by the swinging mechanism a56, and finally the driven shaft d6 outputs the output; in the fifth path, the driven shaft b4 is driven by the gear transmission mechanism b34, the driven shaft c5 is driven by the gear transmission mechanism c45, the driven shaft e7 is driven by the swinging mechanism b57, and finally the driven shaft e7 outputs the power.
As shown in fig. 3, the horizontal twisting motion mechanism includes a housing 1, a driving shaft 2, a driven shaft a3, a driven shaft b4, a driven shaft c5, a gear transmission mechanism a23, a gear transmission mechanism b34, and a gear transmission mechanism c45, wherein the driving shaft 2, the driven shaft a3, the driven shaft b4, the driven shaft c5, the gear transmission mechanism a23, the gear transmission mechanism b34, and the gear transmission mechanism c45 are respectively mounted on the housing 1. The driving shaft 2 is connected with a driven shaft a3 through a gear transmission mechanism a 23; the driven shaft a3 is connected with the driven shaft b4 through a gear transmission mechanism b34, and the driven shaft b4 is connected with the driven shaft c5 through a gear transmission mechanism c 45.
The gear train c45 includes an input gear c42 and an output gear c 51. The input gear c42 is sleeved on the driven shaft b4 and is meshed with the output gear c51 sleeved on the driven shaft c5, and the transmission ratio of the input gear c42 to the output gear c51 is 1: 1.5.
The kinetic energy of the horizontal twisting motion mechanism is input from the driving shaft 2, the driven shaft a3 is driven by the gear transmission mechanism a23, and the kinetic energy is transmitted to the driven shaft a3 and then is output in three paths: the first route is output by a driven shaft a 3; the second path drives the driven shaft b4 through the gear transmission mechanism b34, and is finally output by the driven shaft b4; the third path drives the driven shaft b4 through the gear transmission mechanism b34, drives the driven shaft c5 through the gear transmission mechanism c45 and finally is output through the driven shaft c 5.
As shown in fig. 4, the single-twisting motion mechanism includes a housing 1, a driving shaft 2, a driven shaft a3, a driven shaft b4, a driven shaft c5, a driven shaft f8, a gear transmission mechanism a23, a gear transmission mechanism b34, a gear transmission mechanism e38, and a link mechanism 35, wherein the driving shaft 2, the driven shaft a3, the driven shaft b4, the driven shaft c5, the driven shaft f8, the gear transmission mechanism a23, the gear transmission mechanism b34, the gear transmission mechanism e38, and the link mechanism 35 are respectively mounted on the housing 1. The driving shaft 2 is connected with a driven shaft a3 through a gear transmission mechanism a 23; the driven shaft a3 is connected with a driven shaft b4 through a gear transmission mechanism b34, and the driven shaft a3 is connected with a driven shaft f8 through a gear transmission mechanism e 38; the driven shaft a3 is connected to the driven shaft c5 through a link mechanism 35.
The gear transmission mechanism e38 comprises an input gear e33 and an output gear d 81; the input gear e33 is sleeved on the driven shaft a3 and meshed with the output gear d81 sleeved on the driven shaft f8, and the transmission ratio of the input gear e33 is 1: 3.
As shown in fig. 9, the link mechanism 35 includes a rocker arm f36, a rocker arm e58, a link 351; one end of the rocker arm f36 is sleeved on the driven shaft a3, and the other end of the rocker arm f36 is connected with one end of the connecting rod 351; one end of the connecting rod 351 is connected with the rocker arm f36, and the other end of the connecting rod is connected with the rocker arm e 58; one end of the rocker arm e58 is sleeved on the driven shaft c5, and the other end of the rocker arm e58 is connected with the connecting rod 351.
The kinetic energy of the single-twisting motion mechanism is input from the driving shaft 2, the driven shaft a3 is driven by the gear transmission mechanism a23, and the kinetic energy is transmitted to the driven shaft a3 and then is output in four ways: the first route is output by a driven shaft a 3; the second path drives the driven shaft f8 through the gear transmission mechanism e38, and is finally output by the driven shaft f 8; the third path drives the driven shaft b4 through a gear transmission mechanism b34, and is finally output by the driven shaft b4; the fourth path drives the driven shaft c5 via the link mechanism 35, and is finally output from the driven shaft c 5.
Claims (9)
1. A multi-mode fishing net braiding machine movement mechanism comprises a box body, a driving shaft, a driven shaft a, a driven shaft b, a driven shaft c, a driven shaft d, a driven shaft e and a driven shaft f, wherein the driving shaft, the driven shaft a, the driven shaft b, the driven shaft c, the driven shaft d, the driven shaft e and the driven shaft f are respectively installed on the box body; the driving shaft is connected with a driven shaft a through a gear transmission mechanism a, and the driven shaft a is connected with a driven shaft b through a gear transmission mechanism b; the driven shaft c, the driven shaft d, the driven shaft e and the driven shaft f are connected by adopting any one of the following three connection schemes:
firstly, the driven shaft b is connected with a driven shaft c through a gear transmission mechanism c, the driven shaft b is connected with a driven shaft f through a gear transmission mechanism d, the driven shaft c is connected with a driven shaft d through a swing mechanism a, and the driven shaft c is connected with a driven shaft e through a swing mechanism b so as to realize a three-strand and one-strand braiding mode;
secondly, the driven shaft b is connected with a driven shaft c through a gear transmission mechanism c to realize a flat-twisting weaving mode;
and thirdly, the driven shaft a is connected with a driven shaft f through a gear transmission mechanism e, and the driven shaft a is connected with a driven shaft c through a link mechanism so as to realize a single-twist weaving mode.
2. The multi-mode fishing net braiding machine motion mechanism of claim 1, wherein: the gear transmission mechanism a comprises an input gear a and an output gear a; the input gear a is sleeved on the driving shaft and meshed with the output gear a sleeved on the driven shaft a, and the transmission ratio of the input gear a to the output gear a is 1: 2.
3. The multi-mode fishing net braiding machine motion mechanism of claim 1, wherein: the gear transmission mechanism b comprises an input gear b and an output gear b; the input gear b is sleeved on the driven shaft a and meshed with the output gear b sleeved on the driven shaft b, and the transmission ratio of the input gear b to the output gear b is 1: 2.
4. The multi-mode fishing net braiding machine motion mechanism of claim 1, wherein: the gear transmission mechanism c comprises an input gear c and an output gear c; the input gear c is sleeved on the driven shaft b and meshed with the output gear c sleeved on the driven shaft c, and the transmission ratio of the input gear c to the output gear c is 1: 1.5.
5. The multi-mode fishing net braiding machine motion mechanism of claim 1, wherein: the gear transmission mechanism d comprises an input gear d and an output gear d; the input gear d is sleeved on the driven shaft b and meshed with the output gear d sleeved on the driven shaft f, and the transmission ratio of the input gear d to the output gear d is 1: 2.
6. The multi-mode fishing net braiding machine motion mechanism of claim 1, wherein: the gear transmission mechanism e comprises an input gear e and an output gear d; the input gear e is sleeved on the driven shaft a and meshed with the output gear d sleeved on the driven shaft f, and the transmission ratio of the input gear e to the output gear d is 1: 3.
7. The multi-mode fishing net braiding machine motion mechanism of claim 1, wherein: the connecting rod mechanism comprises a rocker arm f, a rocker arm e and a connecting rod; one end of the rocker arm f is sleeved on the driven shaft a, and the other end of the rocker arm f is connected with one end of the connecting rod; one end of the connecting rod is connected with the rocker arm f, and the other end of the connecting rod is connected with the rocker arm e; one end of the rocker arm e is sleeved on the driven shaft c, and the other end of the rocker arm e is connected with the connecting rod.
8. The multi-mode fishing net braiding machine motion mechanism of claim 1, wherein: the swing mechanism a comprises a cam a, a cam b, a swing arm a and a swing arm b; one end of the swing arm a is sleeved on the driven shaft d, and the other end of the swing arm a is connected with the cam a; the cam a is sleeved on the driven shaft c; one end of the swing arm b is sleeved on the driven shaft d, and the other end of the swing arm b is connected with the cam b; the cam b is sleeved on the driven shaft c, and one end of the swing arm a connected with the cam a is provided with a roller a which is tangent with the outer contour of the cam a; one end of the swing arm b connected with the cam b is provided with a roller b which is tangent with the outline of the cam b.
9. The multi-mode fishing net braiding machine motion mechanism of claim 1, wherein: the swing mechanism b comprises a cam c, a cam d, a swing arm c and a swing arm d; one end of the swing arm c is sleeved on the driven shaft e, and the other end of the swing arm c is connected with the cam c; the cam c is sleeved on the driven shaft c; one end of the swing arm d is sleeved on the driven shaft e, and the other end of the swing arm d is connected with the cam d; the cam d is sleeved on the driven shaft c, and one end of the swing arm c, which is connected with the cam c, is provided with a roller c which is tangent with the outer contour of the cam c; one end of the swing arm d, which is connected with the cam d, is provided with a roller d which is tangent with the outline of the cam d.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201920179927.4U CN209892712U (en) | 2019-02-01 | 2019-02-01 | Multi-mode fishing net braider motion |
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| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201920179927.4U CN209892712U (en) | 2019-02-01 | 2019-02-01 | Multi-mode fishing net braider motion |
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| CN209892712U true CN209892712U (en) | 2020-01-03 |
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| CN201920179927.4U Expired - Fee Related CN209892712U (en) | 2019-02-01 | 2019-02-01 | Multi-mode fishing net braider motion |
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Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN109780156A (en) * | 2019-02-01 | 2019-05-21 | 绍兴通用提花机械有限公司 | A kind of multi-mode fishing net machine movement mechanism |
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2019
- 2019-02-01 CN CN201920179927.4U patent/CN209892712U/en not_active Expired - Fee Related
Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN109780156A (en) * | 2019-02-01 | 2019-05-21 | 绍兴通用提花机械有限公司 | A kind of multi-mode fishing net machine movement mechanism |
| CN109780156B (en) * | 2019-02-01 | 2024-04-09 | 绍兴通用提花机械有限公司 | Multi-mode fishing net braiding machine movement mechanism |
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Granted publication date: 20200103 Termination date: 20220201 |