JPS5953937B2 - Net manufacturing equipment - Google Patents

Description

[Detailed Description of the Invention] This invention relates to a new net manufacturing device, and its purpose is to arrange an odd number of small weight wheels between two large weight wheels with the same diameter. In a net manufacturing device configured such that these strands rotate in opposite directions, if the number of strands constituting each net leg is N, there are 2N bobbin locks arranged at equal intervals around the circumference of each large spindle. In addition to providing a common notch, the number of small spindle rings is set to 2N-3, and each small spindle ring is provided with a bobbin engagement notch at a position that divides its circumference into two, and the diameter of the large spindle ring and the small spindle are provided. To provide a net manufacturing device in which the diameter of a spindle is N:1 and the angular velocity of a small spindle is N times the angular velocity of a large spindle.

Next, an embodiment of the net manufacturing apparatus according to the present invention will be described based on the drawings.

Embodiment I This embodiment shown in FIGS. 1-1 to 1-3 is an embodiment in which the number of strands constituting one net leg 1 is two, and this strand is designated as a in the figure.

Indicated by b, c, and d.

In the figure, A indicates two large spindle wheels formed to have the same large diameter, and each large spindle A is provided with bobbin engagement notches twice as many as the number of strands on its circumferential side.

That is, the number N of strands described in the claims
is 2 in this embodiment, so the number of bobbin engaging notches is 4.

The bobbins around which the strands are wound are engaged with the bobbin engagement notches, and these bobbins are designated by a' to d' in order to correspond to the symbols a to d of the strands.

Further, B is a small fortune wheel B located between each large fortune wheel A, and all of the small fortune wheels B are odd numbers in other embodiments described below, and in this embodiment there is only one. do.

That is, as described in the claims, this one item is derived from 2N-3 items, and in this example, since it is N22, it becomes 4-3 items, and therefore 1 item. .

The small weight wheel B is provided with a notch for engaging the bobbin at a position where its circumference is equally divided into two.

Furthermore, the diameter of this small fortune wheel B is 2 times the diameter of the large fortune wheel A.
N:
1, and in this example, N=2
It is.

Also, the circumferential speeds due to the rotation of the large luck spindle A and the small luck spindle B are both equal, but when comparing the angular velocities, the angular velocity of the small luck spindle B is set to N times the angular velocity of the large luck spindle A, i.e. In this embodiment, it is doubled.

Therefore, in this embodiment, the small luck spindle B rotates twice for each rotation of the large luck spindle A, in other words, when the large luck spindle A rotates one quarter, the small luck spindle B rotates one half. It will rotate.

The other configurations are the same as those of conventionally known manufacturing equipment.

Therefore, as shown in Fig. 1-1, two bobbins a', b', c', and d' are arranged on each large fortune wheel A, and the bobbins are placed in the direction of the arrow shown in Fig. 1-2. Let it rotate.

In the same figure, 1 to 2 show how the large fortune wheel A rotates at a pitch of one-quarter rotation, and the process shown in 2 is a diagram configuring the net leg 1.

In other words, when each bobbin a', b', c', and d' is placed on the big luck spindle A and the big luck spindle A rotates once, one pitch of strands a to d is completed.
Although only one pitch is shown in the figure, it is rotated several times to obtain the desired length.

From E onwards in the same figure, the process of braiding the knitting section indicated by reference numeral 2 is shown, of which E corresponds to the starting point of the knitting section 2 after finishing knitting the net leg 1.

From E onwards, the pitch of the big luck spindle A is shown as a quarter rotation, but after making a quarter turn, the bobbins a' and d' move on the big luck spindle A in each direction of rotation. The other bobbins b' and c' have been transferred to the bobbin engagement notch formed in the small weight wheel B, although the transfer has been made by a quarter of the way.

This transfer of the bobbin from one spindle wheel to another can be accomplished by conventional point valves or groove tracks (both not shown).

In addition, although the state of the small fortune wheel B does not seem to change in the drawing between Ho and Ho, this small fortune wheel B is also rotating, and it rotates by 1/2 of a rotation from Ho to Ho. That means you are doing it.

In other words, when the bobbins b' and c' on the large fortune wheel A reach the position where they come into contact with the small fortune wheel B, in the middle of the transition from the state E to the state , the bobbins provided on the small fortune wheel B are activated. The joint notch also reaches the position where it contacts the large spindle A, and at this point the point valve is activated and the bobbin b',
This causes c' to shift from the big luck spindle A to the small luck spindle B.

This kind of action is the same from step (g) onward, and can be understood by following the rotational directions of the large and small spindle wheels A and B and the moving locus of each bobbin a' to d'.

Then, at the end of the process, the joint section 2 is finished, and the net leg 1 is started again.

The net formed in this way looks like the one shown in Figures 1-3.

Embodiment II The present embodiment shown in FIGS. 2-1 to 2-3 is an embodiment in which the number of strands constituting one net leg 1 is three, and these strands are indicated by a in the figure.

They are indicated by b, c, a, e, and f.

In the figure, A is the large fortune wheel, and B is the small fortune wheel.

The relationship, shape, etc. between the large fortune wheel A and the small fortune wheel B are the same as in the aforementioned embodiment (■), and in this embodiment, N described in the claims is 3. , each big luck spindle A
The bobbin engagement notches provided on the
, and the number of small fortune wheels B is 2N-3=6-3=3
The ratio of the diameter of the large fortune wheel A and the diameter of the small fortune wheel B is N:
1, so the ratio is 3:1, and the small fortune wheel B
The angular velocity of is N times that of the large luck spindle A, that is, 3 times, so when the large luck spindle A rotates once, the small luck spindle B rotates 3 times.In other words, the large luck spindle A rotates one-sixth of the way. As a result, the small fortune wheel B rotates by 1/2 of a revolution.

Further, a' to f' refer to bobbins around which each of the strands a to f are wound, and the symbols are shown to correspond to the strands.

As shown in Figure 2-1, each large fortune wheel A has three bobbins a', b', c', d', e',
f' and rotate it in the direction of the arrow shown in FIG. 2-2.

In the same figure, each large fortune wheel A is shown rotating at a pitch of 1/6 rotation, but in the configuration of the net leg 1, each bobbin a' to f' is a large fortune wheel A. All you have to do is keep it placed at A and rotate the great luck spindle A.

Therefore, according to the figure, I to I show the process of forming the net leg 1, and the subsequent steps show the process of forming the joint section 2.

These processes will be explained with reference to Example I.
, B can be understood by following the rotation directions of the bobbins a' to f' and the transition locus of the bobbins a' to f'.

Other details are the same as in Example (2).

The net thus formed is as shown in FIGS. 2-3.

Embodiment III The present embodiment shown in FIGS. 3-1 to 3-3 is an embodiment in which the number of strands constituting one net leg 1 is four, and these strands are shown as a in the figure.

bs Cy (L e-fs gt h teal.

In the Soshite diagram, A is the large luck spindle, and B is the small luck spindle.

The relationship, shape, etc. between the large luck spindle A and the small luck spindle B are the same as in Example I, and in this example, since N stated in the claims is 4, each large luck spindle The bobbin engagement notches provided on ring A are equally spaced at 2N, or 8
, and the number of small fortune wheels B is 2N-3=8-3=
5. The ratio of the diameter of large fortune wheel A and the diameter of small fortune wheel B is N:
1, so the ratio is 4:1, and the small luck spindle B
The angular velocity of is N times that of the large luck spindle A, that is, 4 times, so when the large luck spindle A rotates once, the small luck spindle B rotates four times.In other words, the large luck spindle A rotates one-eighth of the time. As a result, the small fortune wheel B rotates by 1/2 of a revolution.

Further, a' to h' refer to the bobbins around which each of the strands a to h are wound, and the symbols are indicated to correspond to the strands.

As shown in Figure 3-1, each large fortune wheel A has four bobbins a', b', c', d', e',
f'.

3-2, and rotate them in the direction of the arrow shown in FIG.

In the same figure, each large fortune wheel A is shown rotating at a pitch of 1/8 rotation, but in the configuration of the net leg 1, each bobbin a' to h' is rotated by a large fortune wheel A. It would be better if the great luck spindle A could be rotated while remaining in the position.

Therefore, according to the same figure, I to I show the process of forming the net leg 1, and the subsequent steps show the process of forming the joint section 2.

These processes will be explained with reference to Example I.
, H and the transition locus of bobbins a' to h' can be understood.

Other aspects are the same as in Example I.

The net thus formed is as shown in Figure 3-3.

Embodiment IV The present embodiment shown in FIGS. 4-1 to 4-3 is an embodiment in which the number of strands constituting one net leg 1 is five, and these strands are shown as a in the figure.

b, C, d, e, f, g, h,
11 J is indicated.

Regarding the same figure, the symbols A and B refer to large and small fortune wheels, and the relationship, shape, etc. between the large fortune wheel A and the small fortune wheel B are the same as in the above-mentioned Example I, and this book is the same as the above-mentioned Example I. In the embodiment, since N stated in the claims is 5, the number of bobbin engaging notches provided on each large weight wheel A is 2N, that is, 10, provided at equal intervals, and the number of notches for engaging the bobbin provided on each large weight ring A is 2N, that is, 10 pieces. The number is 2N-3=10-3, and the ratio of the diameter of large spindle A to the diameter of small spindle B is N:1, that is, 5:1, and the angular velocity of small spindle B is is N times that of the big luck spindle A, that is, 5 times, so when the big luck spindle A rotates once, the small luck spindle B rotates 5 times.In other words, the big luck spindle A rotates one-tenth of the way. As a result, the small fortune wheel B rotates by 1/2 of a revolution.

Further, a' to j' indicate the bobbins around which each of the strands a to j is wound, and the symbols are indicated to correspond to the strands.

As shown in Figure 4-1, each large fortune wheel A has five bobbins a', b', c', d', e',
f'.

Arrange h/, 1/, and j/ and rotate in the direction of the arrow shown in Figure 4-2.

In the figure, each large luck spindle A is shown rotating at a pitch of 1/10 rotation, but in the configuration of the net leg 1, each bobbin a' to j' is rotated by a large luck spindle A. It would be better if the great luck spindle A could be rotated while remaining in the position.

Therefore, according to the same figure, the lines 1 to 11 show the process of forming the net leg 1, and the subsequent steps show the process of forming the knotted part 2.

These processes are explained in each spindle A while referring to Example ①.
, B can be understood by following the rotation direction of the bobbins a' to j' and the spindle trajectory of the bobbins a' to j'.

Other aspects are the same as the example construction.

The net thus formed is as shown in Figure 4-3.

Embodiment 2 The present embodiment shown in FIGS. 5-1 to 5-3 is an embodiment in which the number of strands constituting one net leg 1 is six, and these strands are shown as a in the figure.

b, C5d, e, 15g, h, i, and j are indicated by 1.

In the figure, A and B indicate large and small fortune wheels, and the relationship, shape, etc. between the large fortune wheel A and the small fortune wheel B are the same as in Example I described above. In this embodiment, since N described in the claims is 6, the number of bobbin engaging notches provided on each large weight wheel A is 2N, that is, 12, at equal intervals, and the number of small weight wheels B is 2N, that is, 12. is 2N-3=1
2-3 = 9 pieces, the ratio of the diameter of the large fortune wheel A to the diameter of the small fortune wheel B is N:1, so the ratio is 6:1, and the angular velocity of the small fortune wheel B is the same as that of the large fortune wheel B. N times that of A, that is, 6 times. Therefore, if the big luck spindle A makes one revolution, the small luck spindle B turns 6 times. In other words, the big luck spindle A turns 1/12.
By rotating, the small fortune wheel B rotates by half a revolution.

Further, a' to 1' refer to bobbins around which each of the strands a to 1 are wound, and the symbols are indicated to correspond to the strands.

As shown in Figure 5-1, each large fortune wheel A has six bobbins a, b', c', d', e',
f'.

Place ' and 1' on g', h', i', and j', and set 5-2.
Rotate it in the direction of the arrow shown in the figure.

In the figure, each large fortune wheel A is shown rotating at a pitch of 1/12 rotation, but in the configuration of the net leg 1, each bobbin a' to 1' is rotated by a large fortune wheel A. All you have to do is make the Great Luck Weight Wheel A rotate once while it is still placed in the position.

Therefore, according to the figure, I to I show the process of forming the net leg 1, and the subsequent steps show the process of forming the knotted part 2.

These processes can be understood by referring to Example I and following the rotation directions of the large and small spindle wheels A and B and the transition locus of the bobbins a' to 1'.

Other details are the same as in Example (2).

The net thus formed is as shown in Figure 5-3.

The number of other strands N is 7. 8. 9. . . . Even if the increase is made, it is theoretically the same and is based on each of the above-mentioned embodiments, and in all the embodiments of two or more whose explanation is omitted, the large fortune wheel A is increased by 2N. 1
Although it is said that it is rotating at a rotational pitch, this is not an intermittent rotation, but is only described for the convenience of explanation, and it is a continuous rotation.

Also, the drawing shows a state in which 2N-3 small fortune wheels B are arranged between two large fortune wheels A, but this is 1
In actual use, it is made up of many units, and in this case, one Daiun weight wheel A also serves as the Daiun weight wheel of the adjacent unit. Moreover, the connection and arrangement of such units are also possible depending on the design, for example, in a linear shape, a zigzag shape, etc.

Furthermore, since it is mentioned above that only the large weight wheel A is used when forming the net leg 1, the rotation of the small weight ring B, which is not used, is stopped when forming the net leg 1. It is also possible to increase the rotational speed of the large fortune wheel A while stopping it, and these are fully possible by using a clutch or a transmission, for example.

As mentioned above, according to the net manufacturing apparatus according to the present invention,
In the knitting section, each strand always intersects vertically to form a cross-shaped cross section, thus making it possible to form a strong knitting section, and also twisting is added to each strand itself during the knitting process. As a result, a strong net metal body is formed, and since it consists of a combination of large and small weight rings, and depending on the type of connection, it is possible to make it more compact. Furthermore, the number of processes in which the large spindle wheel is inspected every 2N rotation is reduced compared to conventional equipment, which has the effect of improving manufacturing efficiency.

[Brief explanation of drawings]

The drawings show an embodiment of the net manufacturing apparatus according to the present invention, and Fig. 1-1 is a plan view when the number of strands is two, and Fig. 1-2 is an explanation showing the knitting process by this. figure,
Figures 1-3 are explanatory diagrams of the net knitted by this method, and the second
Figure-1 is a plan view when the number of strands is three, Figure 2-2 is an explanatory diagram showing the knitting process, and Figure 2-3.
The figure is an explanatory diagram of the net knitted by this method, Fig. 3-1 is a plan view when the number of strands is 4, Fig. 3-2 is an explanatory diagram showing the knitting process by this, and Fig. 3 -3 is an explanatory diagram of the net knitted by this method, FIG. 4-1 is a plan view when the number of strands is 5, and FIG. 4-2 is an explanatory diagram showing the knitting process by this, Fig. 4-3 is an explanatory diagram of the net knitted by this method, Fig. 5-1 is a plan view when the number of strands is six, and Fig. 5-2 is an explanation showing the knitting process by this method. Fig. 5-3 is an explanatory diagram of the net knitted by this method, 1 is the net leg, 2 is the organization part, A is the large spindle,
B is a small spindle, a-1 is a strand, and a' to a' are bobbins.

Claims (1)

[Claims] 1. In a net manufacturing device in which an odd number of small spindle wheels are arranged between two large spindle wheels of the same diameter and are configured so that these spindles rotate in opposite directions, the strands constituting each net leg are If the number is N, there are 2 at equal intervals around the circumference of each large fortune wheel.
In addition to providing N notches for engaging the bobbin, the number of small spindle rings is set to 2N-3, and each small spindle ring is provided with a notch for engaging the bobbin at a position that equally divides its circumference, and the large spindle is This net manufacturing device is characterized in that the diameter of the ring and the diameter of the small spindle are N:1, and the angular velocity of the small spindle is N times the angular velocity of the large spindle.