JPS63167769A - Connecting apparatus for sheetlike laver - Google Patents

Abstract

PURPOSE:To improve production efficiency by successively and automatically joining laver fed one by one from the first conveying device to laver positioned on the upstream end of the second conveying device forming long beltlike laver. CONSTITUTION:Rectangular sheetlike laver (N) is conveyed one by one in the first conveying device 2. The second conveying device 3 is provided on the downstream side of the device 2 at a lower conveying speed than that of the first conveying device 2. A liquid is applied to wet the upstream end part of the sheetlike laver in the course of conveying in a liquid coating device 4 provided on the upstream side of the second conveying device 3. Furthermore, the end parts of the sheetlike laver overlapped on the device 3 by difference in conveying speed between the device 2 and 3 are pressed while being heated by a pressing roller 6 provided above the second conveying device 3. As a result, since the laver can be automatically joined, production efficiency is improved as compared with that of conventional manual operation and the operation is sanitarily carried out.

Description

DETAILED DESCRIPTION OF THE INVENTION <Industrial Application Field> The present invention relates to an apparatus for continuously connecting sheets of seaweed to form a long belt-like body.

(Prior art and its problems) When mass-producing sushi rolls, a long belt-shaped sheet of nori is moved on a conveyor, rice and toppings are placed on top of the nori, and the sheets are placed on opposite sides of the nori transfer path. A method is adopted in which the rice is continuously rolled with the rice on the inside and the seaweed on the outside using rolling rollers, and then the rolls are sequentially cut into unit lengths.

The above-mentioned long belt-shaped seaweed is formed by continuously connecting rectangular seaweed, but in the past, this work was done manually, which was not only inefficient but also unsanitary.

(Means for Solving the Problems) The present invention discloses a device that can automatically connect rectangular sheets of seaweed into strips with high efficiency.

The present invention is a first method that transports rectangular sheets of seaweed one by one.
a conveying device (2), and a second conveying device (2) that is disposed downstream of the first conveying device (2) and has a slower conveying speed than the first conveying device (2).
A conveying device (3), a liquid coating device (4) that is disposed upstream of the second conveying device and applies a liquid to the upstream end of the sheet-shaped seaweed that is being conveyed to wet it, and the second conveying device (3). The ends of the lobed seaweed (see above) overlapped on the second conveying device (3) due to the difference in conveying speed between the first conveying device (2) and the second conveying device (3). It consists of a pressing roller (6) that presses while heating.

(Operations and Effects) The upstream end of the rectangular seaweed transported by the first transport device (2) is wetted by being coated with a liquid by the liquid coating device (4) on the way to the second transport device (3).

The next piece of seaweed on the first conveying device (2) is transferred to the second conveying device (3) in the same manner as above, but at this time, the conveying speed of the first conveying device (2) is lower than the second conveying speed. 2nd because it's fast
The first conveying device (2) is placed on the wet part of the seaweed on the conveying device (3).
) to the second conveying device 3) with the downstream ends of the seaweed being overlapped, and this overlapping portion is pressed by a pressing roller (6).
) is heated and pressed to join the seaweed.

The above operation is continuously repeated, and the seaweed supplied one by one from the first conveyance device (2) is sequentially joined to the seaweed located at the upstream end of the second conveyance device (3), and a long strip of seaweed is formed. Since seaweed can be automatically joined as described above, the production rate is improved compared to the conventional manual method, and it is also sanitary.

(Example) Figure 1 is a plan view of the main parts of the seaweed connection device, and Figure 2 is the same as Figure 1.
It is a cross-sectional view along the -■ line.

The rectangular pieces of seaweed are conveyed one by one from the left side to the right side in the drawing, and are connected one after another during conveyance and wound up on a drum (7).

As shown in Figure 7, the length of the rectangular seaweed N is 185 m.
m, the width W is 105 m+n, the longitudinal direction is aligned with the conveying direction, and the joining margin S is 10+n+11.

The seaweed connecting device includes, in order from the upstream side to the downstream side of the base (1), a first conveying device (2), a liquid applicator for wetting the seaweed joint S (4), a twenty-first conveying device (3), and A winding drum (7) is provided and a pressure roller (6) is provided above the upstream end of the 2112nd feeding device (3).

The first conveying device (2) has a push claw (22) attached to an endless chain (21) that rotates in a vertical plane, and the push claw is installed on a horizontal guide plate (11) that guides the transfer of seaweed. The seaweed N is conveyed by pushing the seaweed N toward the downstream side with the claws. The spacing between the pushing claws (22) (22) corresponds to the length of the seaweed N, and the seaweed N is conveyed with almost no gaps.

The guide plate (11) is provided with a parallel guide wall (13) <13> that guides the seaweed N straightly.

The drive shaft (23) of the first conveying device (2) is the intermediate shaft (8
1) is connected to the motor <8).

The automatic seaweed feeding device (
(not shown) are connected, and the pushing claw (22) of the conveying device
(22) Seaweed is supplied in between.

As shown in FIG. 6, the liquid applicator (4) applies a liquid to the joint width S of the seaweed in order to connect the seaweed N, and approaches the downstream end of the guide plate (11). A roller (40) and a liquid application roller (41) are placed on both sides of the seaweed transfer path.
It is configured by facing each other.

The applicator roller (41) has a shaft that is thinner than the roller (40), and a sponge bar (42) is attached to the shaft in the direction of the shaft. It is formed by discarding 1 fuze/2 ptAq.

The applicator roller (41) and the receiver are equipped with gears (44) and (45) that mesh with each other, and the roller (40) is equipped with an electromagnetic clutch with a brake (82) and the intermediate shaft (81). It is connected to a motor (8) that drives the 1112th sending device (2) through the motor.

Both rollers (40)<41) rotate in a direction that draws the seaweed N into the second conveyance device (3), and the application roller (41)
When the bar (42) is facing downward, the sponge (43) comes into contact with the roller (40).

A liquid supply device (5) is arranged above the application roller (41), and the supply device (5) supplies the liquid in the liquid tank (51) to a horizontally long distribution pipe 52) having a plurality of nozzles (53). The liquid dripping from the nozzle (53) is caused to slide on the inclined plate (54) and adhere to the metal roller (55), and is transferred to the coating roller (41) via the sponge roller (56) in contact with the metal roller. The liquid is applied to the sponge <43), and the sponge attachment of the applicator roller (41) is done using the bar (42>).
A sponge roller (43) is rotatably disposed at a height where it contacts the sponge (43) of the bar when the bar is facing upward.

Pipe (57) connecting tank (51) and distribution pipe (52)
) is equipped with an on-off valve 58), and the on-off valve (
58) is operated intermittently by a timer or mechanically, and the nozzle (58)
From 3), liquid is discharged at regular intervals.

When the sponge (43) of the applicator roller (41) comes into contact with the sponge roller (56), the sponge roller (56) rotates by friction, and the rotation of the sponge roller causes the metal roller in contact with the roller. (5
5) rotates, and the inclined plate (54) can evenly dye the sponge (43) of the application roller (41) with the liquid.

The liquid can be any type of liquid, such as water or alcohol, as long as it can wet the seaweed.

Each rotation of the coating roller (41) coats the liquid onto the joining margin S at the upstream end of the seaweed passing through the coating device (4).

The 21st feeding device (3) is a belt conveyor, and the width of the belt (31) is slightly larger than the width W of the seaweed. The receiver is connected to a rotating chino (83) that drives the roller (40), and the roller (40) and the second conveyance device (3) are driven synchronously.

As shown in FIG. 3, a pressure roller (6) is disposed above the belt support roller (32) at the upstream end of the second conveyance device (3) so as to be able to approach and move away from the support roller.

Both ends of the pressure roller (6) are rotatably supported by a driven lever (61) pivoted in a vertical plane on the base (1), and the free end of the lever is connected to a drive lever (61) provided below the lever.
62) via a connecting member (69).

A spring (61a) that biases the pressure roller (6) in an upward direction is connected to the driven lever (61).

A roller (64) is pivotally supported at the center of the drive lever (62), and a cam (63) attached to the end of the belt support roller (32) at the upstream end of the second conveyance device (3) is rotated between the rollers and the drive lever (62). 6
4) rotates downward against the spring (61a), and the driven lever connected to the drive lever also follows this and descends, thereby causing the pressing roller to rotate against the belt support roller (32). Press (Figure 5).

The pressure roller (32) has a built-in heater (60) and is constantly energized by a known rotary contact (not shown) connected to the pressure roller.

Due to the operation of the second ffi feeding device (3), the cam (63) rotates, and the pressure roller (6) moves up and down as shown in Fig. 3. During the time when the roller is descending, the seaweed joining margin S is The time taken to pass through the roller is about five degrees longer.

The belt supporting roller (32) at the upstream end of the 211i1 feeding device (3) has a first ffi wheel (65), and the pressing roller (6) has a second gear (66) that can mesh with the first gear (65). It is attached.

A third gear (67) is attached concentrically to the pivoting center of the driven lever (61) so as to be rotatable regardless of the pivoting of the lever, and the third gear (67) meshes with the second gear (66). do.

The third gear (67) and the first gear are located below the third gear (67).
A fourth gear (68) meshing with the gear (65) is mounted on a bearing.

The first gear (65) to the fourth gear (68) are formed in the same shape and rotate at the same speed, and as described above, the driven lever (61)
) rises and the 1st gear (65) and 2nd gear (66) are disengaged, the rotation of the 1i-wheel (65) on the support roller (32) connected to the motor (8) will continue. 4th gear (6
8) and the 2nd tn car (66) via the 3rd @ car (67)
, the first gear (65) and the second gear (66
) changes synchronously, so that the driven lever (61)
When the gear (65) and the second gear (66) are lowered, the first gear (65) and the second gear (66) mesh without any problem.

The belt support roller (33) at the downstream end of the second conveying device (3)
), and a belt (31) on the intermediate support roller <34).
) The disk (35) (35) is freely rotatably placed in contact with the disk (35). The disc (35) serves to lightly press the seaweed on the belt (31).

A drum (7) for winding up the seaweed strip is provided outside the downstream end of the second conveying device (3), and a winding motor (71) is connected to the drum (7). As shown in FIG. 2, energization of the winding motor (71) is controlled by a seaweed tension detection device (72) provided at the downstream end of the second conveyance device (3).

The tension detection device (72) has a pair of arms (73) that are rotatably arranged in a vertical plane on the base (1).A guide bar (74) is supported between the arms (73).
Since the balance weight (75) is connected to the top, the strip of seaweed is wound around the drum (7) through the guide bar (74).
The arm swings depending on the amount of tension applied to the seaweed, and the height position of the guide bar (74) changes. This change is detected by a position detector (not shown) and the winding motor (
By controlling the power supply to 71), it is possible to continuously wind up the seaweed while maintaining an appropriate tension so as not to cut the seaweed.

As mentioned above, the first conveyance device (2) and the second conveyance device (3) are driven by the motor (8) of the rotation transmission gear (1-), but due to the difference in the number of teeth of the rotation transmission gear, the second conveyance device (3) is driven by the motor (8) of the rotation transmission gear. 3) per unit time that the support roller (32) rotates once, the first lit
The feeding device (2) is the entire length of the rectangular seaweed, that is, 185 +n
+ Mouth feeding, the second conveying device (3) feeds the seaweed by a length reduced by joining allowance S f from the total length of the seaweed, that is, 1751.

Therefore, the joining distance S of the upstream end of the nori on the upstream side on the second conveying device (3) and the downstream end of the nori supplied from the 11p1 feeding device (2) are 10+am immediately before the pressing roller (6). The state of overlapping with the overlapping margin of fIl! When the motor (8) is driven at step i, the overlapping portions are pressed by the pressure roller (6) and joined together.

As long as the seaweed is continuously supplied from the first conveyance device (2) to the second conveyance device (3), the difference in the feed speeds of the first and second conveyance devices (3) causes the seaweed to fall just before the pressure roller (6). overlap, the overlapping parts are joined in the same manner as above, and the seaweed is connected in a band shape on the second conveying device (3), and the seaweed is transferred to the drum on the downstream side (3).
7).

However, if the supply of seaweed from the first conveying device (2) stops even for one pitch of the device, the seaweed cannot be continuously connected.

In the embodiment, in preparation for such a case, the first conveying device (2)
When the supply of seaweed from the second transport device (3) and coating device (4) is stopped at a position that does not interfere with the next start, the operation of the second transport device (3) and coating device (4) is stopped at a position that will not interfere with the next start, and the operation of the second conveyance device (3) and coating device (4) is stopped at a position that will not interfere with the next start, and the operation of the second conveyance device (3) and coating device (4) is stopped at a position that does not interfere with the next start, and 2
Stopping and operating the conveying device (3) and coating device (4)
Starting means are provided.

The stop/start means is a coating device (4) as shown in Figure 1.
) and the second transport device (3), a detector (9) such as a phototube that detects the presence or absence of the passage of seaweed in the transition path of the seaweed, is fixed to the drive shaft (23) of the first transport device (2). The first timing cam (91) and the coating device (4) are mounted on rollers (40
), and first and second limit switches (93) (, 95) operated by both cams (91, 92).

In the state where the detector (9) detects passage of seaweed, the first
The clutch (82) is engaged from the time when the detection piece (94) of the first limit switch (93) corresponds to the valley surface (91a) of the cam (91), and the coating device (4) and the second conveyance device 3) are activated. (Drive.

When the detector 9) detects that the seaweed does not pass, the second limit switch (92) is placed on the valley surface (92a) of the second cam (92).
When the detected piece 96) of 95) is detected, the clutch (82) is disconnected and the coating device (4) and the second conveying device (3) are disconnected.
) stops.

The timing cams (91) and (92) are connected to the drive shaft of the first conveying device (2) and the bearing of the coating device (4) by a bolt (97) passed through an arc hole (96) with the rotation center as the radial center. Flange (20) protruding from (40) (3
The clutch (82) is fixed so that its phase can be adjusted with respect to the clutch (82), and the timing of turning the clutch (82) on and off is set as follows.

The timing to stop the second conveyance device (3) is such that the joining margin of the upstream end of the seaweed on the second conveyance device (3) is
6) When the position is slightly upstream, the timing for restarting the first conveying device (2) and liquid coating device (4) is at the downstream end of the seaweed supplied from the first conveying device (2). This is when it slightly overlaps the upstream end of the seaweed of the second conveying device (3).

As a result, the first transport device (2) to the second transport device i!
Even if the supply of seaweed to the (3) side is cut off, the second conveying device (3)
) The seaweed on top next waits at a position where its ends overlap with the seaweed sent from the first imaging and transmitting device (2), so the seaweed can be joined continuously.

In addition, by providing the above-mentioned stop/start means,
For example, 50 m +
The seaweed is transferred one sheet at a time to the second conveying device (3
) side, it is possible to connect the seaweed continuously, and if the seaweed can be conveyed at intervals above the first conveying device (1) in this way, the seaweed can be connected to the first conveying device (1). This makes it easier to supply timing and can be done manually.

The present invention is not limited to the above-mentioned embodiments, and various modifications can be made within the scope of the claims.

[Brief explanation of the drawing]

Figure 1 is a plan view of the seaweed connection device, Figure 2 is Figure 1 - ■
3 is a sectional view taken along the line, FIG. 3 is an oblique view of the liquid coating device and the second conveyance device, FIG. 4 is a side view of the state in which the pressure roller releases the seaweed transfer path, and FIG. FIG. 6 is a side view of the state in which the overlapping portions are pressed, FIG. 6 is a slope view of the liquid coating device, and FIG. 7 is a slope view of seaweed.

Claims (1)

[Claims] (1) A first conveying device (2) that conveys rectangular sheets of seaweed one by one; and a first conveying device (2) that is installed downstream of the first conveying device (2) and has a slower conveying speed than the first conveying device (2). a second conveyance device (3); a liquid coating device (4) disposed upstream of the second conveyance device for wetting the upstream end of the sheet-like seaweed during conveyance; ), and due to the difference in conveying speed between the first conveying device (2) and the second conveying device (3), the edges of the sheets of seaweed that overlap on the second conveying device (3) are heated and pressed. Pressing roller (
6) A sheet-shaped seaweed connection device comprising: