JPS626893B2 - - Google Patents

Description

[Detailed Description of the Invention] Recently, the use of wire mesh as a substitute for column bars, beam auxiliary bars, and floor reinforcing bars in reinforced concrete structures has been suddenly attracting attention from the viewpoint of labor saving. However, in the past, when manufacturing wire mesh, the work was intermittent and required manpower, which was problematic in terms of labor saving and productivity.

The present invention has been proposed in view of the above circumstances, and includes mesh grooves symmetrically provided on each outer circumferential surface to create a plurality of wire passing spaces between opposing surfaces in the axial direction of the roll. A pair of upper and lower rolling rolls formed side by side are rotated to form every other space and every other remaining space on a diagonal line along the roll axis of the mesh of the mesh grooves. When reciprocating repeatedly in the opposite direction by a distance equivalent to one-half of moving the second wire rod guide member so as to synchronize with the movement of the every other space, and move the second wire rod guide member so as to synchronize with the movement of the remaining every other space, A plurality of wire rods are supplied from the wire rod guide members to the respective spaces, and when the intersections of the mesh grooves move between the opposing surfaces and the respective spaces overlap, the wires are The purpose of this invention relates to a method for manufacturing a wire mesh, which is characterized in that the wire mesh is bent into a mountain shape and crimped at the same time, and at this time, the wire rods are energized through the wire guide members to weld the wire rods at high frequency. The place where
Wire mesh can be manufactured automatically and continuously. It is possible to eliminate the overlap of wire rods that occurs at wire rod intersections. The power required for welding can be reduced. Another object of the present invention is to provide an improved method for manufacturing a wire mesh that can improve the strength of the wire intersections.

Next, the present invention will be explained with reference to the embodiment shown in the drawings. In Fig. 1, 1 and 2 are a pair of upper and lower rolling rolls,
Mesh grooves 3 are symmetrically provided on each outer peripheral surface. The mesh grooves 3 of the rolling rolls 1 and 2 are semicircular grooves formed around the helical centerline (see A in FIGS. 2 and 3). Therefore, between the opposing surfaces of the rolling rolls 1 and 2, the grooves having a semicircular cross section completely coincide to form a plurality of circular wire passing spaces 4 (see FIG. 4) in the axial direction of the rolls. It will be formed so that it is lined up with. Furthermore, when the rolling rolls 1 and 2 are rotated in the direction of the arrow in FIG. 2 of the diagonal line along the axis (see L in Figure 8)
It appears to repeatedly move back and forth in the opposite direction by a distance equivalent to 1/2 (see L ₁ in FIG. 8), and when each space 4 moves to the stroke end, the adjacent ones overlap. The cross-sectional area of the space during this polymerization is approximately twice the cross-sectional area of the wire rods 5a to 5f (see Figure 8), and the cross-sectional area of the space other than during polymerization is approximately twice that of the wire rods 5a to 5f (see Figure 8). 5f). Further, 6 in FIGS. 1 and 5 is a drive shaft for driving the rolling roll 1, 7 is a drive shaft for driving the rolling roll 2, 8 in FIG. 5 is a gear fixed to the drive shaft 6, and 9 is a drive shaft for driving the rolling roll 1. The gear meshed with the same gear 8, 11 is a bevel gear, 10 is the same gear 9 and the same bevel gear 1
1 is a bevel gear meshed with the bevel gear 11, 13 is a crankshaft integral with the bevel gear 12, and 14 and 14' are 180 degrees to the crankshaft 13.
These are crank pins with different phases. The locus of movement of the crank pins 14, 14' is shown in FIG. 6 by dashed lines. 5 and 6, 15 is a sliding piece that is reciprocated by the crank pin 14, 16 is a sliding piece that is reciprocated by the crank pin 14', 17 is a wire guide member fixed to the sliding piece 15, and 18 is a wire rod guide member fixed to the sliding piece 16, and the stroke of the sliding piece 15 and the wire rod guide member 17, and the stroke of the sliding piece 16 and the wire rod guide member 18 are determined by the crank pin 14,
14' is equal to the diameter d of the movement trajectory. Further, this diameter d and the moving distance L ₁ of each of the spaces 4 are equal. Further, reference numeral 19 denotes a plurality of wire rod guide pieces provided on the wire rod guide member 17 at a distance of 2d, and numeral 20 denotes a plurality of wire rod guide pieces provided on the wire rod guide member 18 at a distance of 2d. , 5c, 5e, every other space 4 is leftward by a distance L ₁
When moving by a distance of
When each space 4 in the former moves by a distance L ₁ to the right, each space 4 in the latter moves by a distance L ₁ .
moves to the opposite left by a distance L ₁ , but the sliding piece 15, wire guide member 17, and each guide piece 19 move in synchronization with the movement of each space 4 of the former.
In addition, the sliding piece 16, the wire guide member 18, and each guide piece 2
0 is adapted to move in synchronization with the movement of each space portion 4 of the latter. Also, 21 in Figure 8 is the power supply,
22 is a camshaft. Note that the camshaft 22 is designed to rotate once while the crankshaft 13 rotates by one-half. Further, 23 is a switch operated by the same camshaft 22, 24 is a high frequency oscillator, 2
5 is the grit circuit terminal of the high frequency oscillator 24,
High frequency oscillator 2 from power supply 21 via switch 23
A negative voltage is applied to the grit circuit terminal 25 of No. 4. Also, 26 is a high frequency oscillator 24
The plate circuit terminal 26 is connected to each of the guide pieces 19 and 20 via a conductive wire and contact pieces 27 and 28. The high-frequency oscillator 24 sends out a high-frequency undamped oscillating current when the switch 23 is off, and does not send out a high-frequency undamped oscillating power when the switch 23 is on.
4 is conventionally known, and further explanation thereof will be omitted.

Next, the operation of the device will be explained. When the pair of upper and lower rolling rolls 1 and 2 are driven, the wire rods 5a, 5c,
5e passes through every other space 4 and wire rod 5
b, 5d, and 5f pass through every other space 4
and repeatedly move back and forth in opposite directions by a distance _L1 . Further, at this time, the wire guide member 17 repeatedly reciprocates in synchronization with the movement of each of the former spaces 4, and the wire guide member 18 repeatedly reciprocates in synchrony with the movement of each of the latter spaces 4. Therefore, each of the wire rods 5a to 5f can be smoothly supplied to each of the spaces 4. Further, when the intersecting portions of the mesh grooves 3 provided on the rolling roll 1 and the mesh grooves 3 provided on the rolling roll 2 move between the opposing surfaces and the respective spaces 4 overlap, each of the wire rods 5a ~5f is bent into a mountain shape and crimped at the same time. That is, the wire rod 5a,
If the space 4 through which the wires 5c and 5e pass is moved to the right, and the space 4 through which the wires 5b, 5d, and 5f are moved to the left, when they move by a distance L ₁ and merge, the wires The wire rods 5b, 5c, 5d, 5e, 5f, 5g, (5
g (not shown) are crimped. Also, at this time, the high frequency undamped oscillating current is transmitted to the high frequency oscillator 2.
4 to each of the wire rods 5b to 5g, and the peak portions are welded. In addition, the wire rods 5a, 5c, 5
After the above-mentioned merging, the space 4 through which wires e pass starts to move to the left, and the space 4 through which the wires 5b, 5d, and _5f pass to the right after the above-mentioned merging. When merging, wire rod 5
a, 5c, 5e and the wire rods 5b, 5d, 5f are bent into a mountain shape in the opposite direction, and at the same time the wire rods 5a, 5b, 5c, 5d, 5e, 5f are crimped. At this time, a high frequency undamped oscillating current is supplied from the high frequency oscillator 24 to each of the wire rods 5a to 5f to weld the peaks. Since the above operations continue, the manufactured wire mesh is continuously discharged from the opposite side of the rolling rolls 1 and 2.

As described above, the wire mesh manufacturing method of the present invention is such that the mesh grooves 3 are symmetrically provided on each outer circumferential surface, and a plurality of wire passing spaces 4 are arranged between the opposing surfaces in the axial direction of the roll. By rotating the pair of upper and lower rolling rolls 1 and 2 formed in When each rolling roll ₁ ,
Among the first and second wire rod guide members 17 and 18 disposed at the wire rod supply position in front of the wire rod supply position 2, the first wire rod guide member 17 is synchronized with the movement of each of the every other spaces, Further, the second wire rod guide member 18 is moved in synchronization with the movement of every other remaining space, and the plurality of wire rods 5 are moved from the wire rod guide members 17 and 18 to each of the spaces 4. When the intersecting portions of the mesh grooves 3 move between the opposing surfaces and the spaces 4 overlap, the wires 5 are bent into a mountain shape and crimped at the same time. That is, the space 4 through which the wire rods 5a, 5c, and 5e pass.
If the space 4 through which the wire rods 5b, 5d, and 5f pass is moved to the left, the distance is
When the wires 5a and 5 move by L ₁ and merge,
c, 5e in a mountain shape parallel to each other, wire rods 5b, 5
At the same time, bend wires 5b, 5c, 5d, 5e, and 5g into mountain shapes in opposite directions.
Crimp. At this time, each wire guide member 1
Since the wire rods 5 are energized through the wires 7 and 18 and the wire rods 5 are welded at high frequency, wire mesh can be manufactured automatically and continuously, saving labor and improving productivity. This has the effect of reducing manufacturing costs.

In addition, in the method for manufacturing a wire mesh of the present invention, when the spaces 4 are polymerized as described above, the peaks of each wire 5 are crimped by the spaces 4 that are polymerized in the same manner, so that the wire mesh can be seen at the intersections of the wires. This has the effect of eliminating overlapping of wire rods.

In addition, in the method for manufacturing a wire mesh of the present invention, the wire rod guide member is used only when the space portions 4 are polymerized as described above and the peak portions of the wire rods 5 are crimped by the space portions 4 that are polymerized. 17 and 18 to high-frequency weld the peaks of each wire 5.
This has the effect of reducing the power required for welding compared to the case where the welding material is preheated by an induction heating device.

Further, since the method for manufacturing a wire mesh of the present invention combines crimping and high-frequency welding as described above, it has the effect of improving the bonding strength at the wire crossing portions.

Although the present invention has been described above with reference to embodiments, the present invention is of course not limited to these embodiments, and various design modifications may be made without departing from the spirit of the present invention. It is.

[Brief explanation of the drawing]

FIG. 1 is a perspective view showing the implementation status of the wire mesh manufacturing method according to the present invention, FIG. 2 is a plan view of a rolling roll,
Fig. 3 is a developed view of the outer peripheral surface of the rolling roll, Fig. 4 is a longitudinal sectional front view showing the space for passing the wire rod formed between the opposing surfaces of the upper and lower forming rolls, and Fig. 5 is each wire guide. A plan view showing the member and its drive mechanism, FIG. 6 is a longitudinal sectional front view taken along the arrow line in FIG. 5, FIG. 7 is a longitudinal sectional side view taken along the arrow line in FIG. It is an explanatory view showing the relationship between an oscillator, each wire guide member, and each wire. DESCRIPTION OF SYMBOLS 1, 2... Rolling roll, 3... Mesh groove, 4... Wire passing space part, 5 or 5a-5f... Wire rod, 17
...First wire guide member, 18...Second wire guide member, L...Length of the diagonal line along the roll axis of the mesh of the mesh groove 3, _L1 ...Length equivalent to half of the diagonal line L difference.

Claims (1)

[Claims] 1. A pair of upper and lower rolling rolls each having mesh grooves symmetrically provided on their respective outer circumferential surfaces and a plurality of wire passing spaces formed between opposing surfaces in the axial direction of the rolls are rotated. 1 out of each space
The alternate space portions and the remaining every other space portion are defined by two diagonal lines along the roll axis of the mesh of the mesh groove.
When reciprocating repeatedly in the opposite direction by a distance equivalent to The guide member is moved in synchronization with the movement of each of the every other spaces, and the second wire guide member is moved in synchronization with the movement of each of the remaining spaces, so that a plurality of wire rods are moved. supplying the wire rods from the respective wire rod guide members to the respective spaces,
The intersecting portions of each of the mesh grooves move between the opposing surfaces,
When each of the spaces overlaps, each wire is bent into a mountain shape and crimped at the same time, and further, at this time,
A method for manufacturing a wire mesh, characterized in that the wire rods are high-frequency welded by applying current to the wire rods through the wire rod guide members.