JP3044100B2 - Length mark device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a length marking device for sequentially marking a measuring mark or the like at predetermined intervals on a running printed cable.

[0002]

2. Description of the Related Art The inventors of the present invention have researched, developed and applied for a length mark device for sequentially engraving measuring marks and the like at predetermined intervals on a running printed cable without measuring errors (Japanese Patent Application No. Hei. No. 141915). This length mark device 10
As shown in FIG. 3, a length mark is engraved at predetermined intervals on the surface of the cable 2 to be printed, and a printing means 30 for engraving a company name and the like, and a moving distance of the cable 2 from a predetermined position, that is, A measuring means 4 for continuously measuring the length of the cable 2 to be printed, a take-up means 5 for taking up the printed cable 2 at a predetermined linear speed and sending it to a winding drum (not shown); An operation control means 6 for controlling the operation of the printing means 4 based on the measuring information 2A and the linear velocity information 4A from the measuring means 4 and the taking-in means 5 is provided.
The printing means 30 has a diameter D [mm] and a circumferential length πD = 10.
A printing roll 20 having an electrically heated first print marking 21 for marking a strip length count on said printed cable 2 at one point on its own circumference; A second print engraving portion 21A for engraving a product name, a company name, and the like is provided between the long engraving and the strip engraving.
m] interval), by the function of the printing and engraving portion 21, for example, the strip length n, ie, [1],
[2], ..., [n] and [SWCC SHOWA1990 0.4 x 200
P], and this print roll 20
And co-rotated to rotate integrally with each other, and formed at a rotation ratio of 1: 1.
The second sprocket 34 that transmits the rotational force to zero and the drive motor 1 (37) that rotates in response to the control signal 5A from the operation control means 6 rotate and rotate via the chain 35. A first sprocket 33 rotating at the same rotation ratio as the second sprocket 34 for driving the second sprocket 34 to rotate, and a first sprocket 33
And the first sprocket 33
The rotation state of the printing roll 20, that is, the rotation state of the printing roll 20, is detected, and when the printing roll 20 makes one rotation, the pulse signal is turned “ON”; otherwise, the pulse signal is turned “OFF”. The first pulse transmitter 39 sends the information 1A to the operation control means 6.

[0005] The printing roll 20 is provided with the printing engraving section 2.
Circumferential length πD of one outer circle (dotted line in the figure) = 1000 [m
m], for each revolution, the function of the printing and engraving portion 21 allows, for example, a strip length n,
[1], [2],..., [N] are printed. 20A indicates a balance weight.

The measuring means 4 includes guide rolls 41, which are arranged on the cable 2 to be printed along the longitudinal direction thereof, facing each other.
A measuring roll portion 40 composed of a measuring roll 43 that is put on the belt 4A and rotates on the belt 4A;
A second output of the measuring information (pulse signal signal) 2A to the operation control means 6 for each rotation amount of the measuring roll 43 from a predetermined position, that is, for every unit rotation amount (10 [mm] in this embodiment). And a pulse transmitter 45.

The take-off means 5 clamps the cable to be printed 2 between guide rolls 51 and 52 wrapped around a belt 5A and guide rolls 53 and 54 wrapped around a belt 5B, and drives the drive motor 2 (38). As a result, the cable 2 is rotated in the direction of the arrow in the figure, and the cable 2 to be printed is drawn in the direction A in the figure at a linear velocity C (0 to 30 [m] / min in the present embodiment). ) Has a function of outputting the linear speed information 4A corresponding to the linear speed C to the operation control means 6 by the tachogenerator 42. As shown in the drawing, the operation control means 6 is provided in parallel with the printing means 3 and responds to the linear velocity information 4A to cause the drive motor 1 (37) to send the print roll 20 to the linear velocity if necessary. A drive control unit 6A that outputs a control signal 5A for driving at a rotation speed of C ′ (in the present embodiment, 10020 [mm] / min when the pickup is performed at 10 [m] / min), and the rotation information 1A The length information 2A is input, and the drive control unit 6A is input.
And an operation control unit 6B that outputs an operation state instruction signal 16.

Reference numeral 70 denotes a copy tape roll around which a copy tape is wound, and reference numeral 72 denotes a copy tape.

Here, a specific operation of the operation control means 6 will be described with reference to FIG.

First, it is assumed that the take-up means 5 operates and the printed cable 2 moves at a linear velocity = 10000 [mm] / min.

[0009] First, the operation control unit 6B transmits the scale information 2A.
Is set to the initial value = 0 (step 1).

Next, the operation state instruction signal 16 is set to "operation instruction", sent to the drive control unit 6A, and the control signal 5A is output to the drive motor 37. ′ (Step 3). Subsequently, in step 5, it is determined whether or not the print roll 20 has made one rotation. More specifically, it is determined whether or not the rotation information 1A is "ON". The processing in step 3 is continued until the operation is completed. If the processing is “ON”, the processing proceeds to step 7 and the operation state instruction signal 1 sent to the drive control unit 6A
6 is set to “operation stop instruction”, and the rotation of the print roll 20 is stopped and controlled. Then, the operation control unit 6B performs the measurement information 2
It is determined whether the value of the pulse signal counter D of A is "100", that is, whether the measuring means 4 has measured 1000 [mm] (step 9). The process is continued. If D = 100, the pulse signal counter D is reset, the operation state instruction signal 16 is set to “operation instruction”, the print roll 20 is driven to rotate, and 1000 with measuring means 4
[Mm] The length n is marked on the measured position. Hereinafter, a series of operations are repeated.

The printing roll 20 has a linear velocity C '= 100
It rotates at 20 [mm] / min.
m] takes about 5.99 [seconds]. On the other hand, the measuring roll 43
Since rotation is performed at a linear velocity C = 10000 [mm] / min, one rotation, 1000 [mm], requires 6 [seconds]. That is, the rotation of the print roll 20 is controlled to stop by 0.11 [second] immediately before the printing of the strip length n.

Next, the overall operation of this embodiment will be described with reference to FIG. Here, the pick-up means 5 determines that the linear velocity C =
At 10000 [mm] / min, the cable 2 to be printed is picked up,
The print wheel 20 is in a state where the line length n = 1 is engraved.

First, the measuring means 4 sends the measuring information 2A, the printing means 30 sends the rotation information 1A to the operation control section 6B, and the taking-off means 5 drives the linear velocity information 4A. The operation is transmitted to the control unit 6A (steps 20 and 22), and the operation control unit 6B outputs the operation state signal 16 to the drive control unit 6A as an "operation instruction" to drive the printing unit 30 (step 24). Next, it is determined whether or not the print roll 20 has made one revolution (step 26).
The process of step 24 is continued, the printing roll 20 is driven, and when one rotation is made, the process proceeds to step 28, and the printing roll 20 is controlled to stop. And the measuring means 4 is 100
It is determined whether or not 0 [mm] has been measured (step 30).
If it is not 00 [mm], the process in step 28 is continued. If it is 1000 [mm], the pulse signal counter D is reset (step 32), and the flow returns to step 24 to print. The roll 20 is driven and controlled.
Hereinafter, a series of operations is repeated, and on the cable 2 to be printed,
At the interval of 1000 [mm], the strip lengths “1”, “2”,.
Mark “n” and [SWCC SHOWA 1990 0.4 × 200P]. According to an experiment, the error between the strip length stamp 1000 [mm] and the actually measured length 1000 [mm] can be reduced to 50 [mm] or less, and a very accurate strip length that can be ignored in practical use can be stamped.

The difference between the linear speed C and the linear speed C 'may be selected as appropriate in consideration of slip, rotation speed and the like. Also,
The rotation detecting means of the printing roll 20 and the measuring roll 43 is not limited to the pulse signal transmitter.

[0015]

However, the length marking device 10 according to the above-mentioned conventional example, in order to imprint a stamp length on the printed cable 2 at a position corresponding to the measured length, requires a linear velocity of the printed cable 2. Since the printing roll 20 is driven to rotate at a rotation speed (linear speed) C ′ slightly higher than C, the second print engraving portion 21A having a long number of engraved characters has a long contact time with the cable 2 to be printed. There was a problem that "slip" occurred between the cable 2 and the second print marking portion 21A, and the marking was "blurred".

[0016]

SUMMARY OF THE INVENTION The object of the present invention is to improve the disadvantages of the prior art described above, and to engrave a stamp length on a printed cable at a position corresponding to the measured length, and to increase the length of characters such as product names and company names. It is an object of the present invention to provide a length mark device capable of imprinting with quality.

[0017]

Accordingly, in the present invention, a printing roll for engraving a predetermined length mark and a character string on a cable to be printed with a circumferential length being a unit printing interval length, and a printing roll and a cable for printing the cable. A printing means having a guide roll whose circumferential length for driving the printing roll following the movement is a unit printing interval length, and a moving amount of the printed cable provided on the take-up machine side from the printing means is measured. A length measuring device for measuring and outputting the measuring information, and a take-off means for picking up the printed cable at a predetermined linear velocity, wherein a shaft portion of the printing roll and the guide roll is provided. A drive control unit for controlling the direct connection and release with the shaft unit as needed, and connecting the respective drive control units via a rotational force transmitting means, and attaching this mark to the shaft unit of the printing roll. Take configuration that features equipped with forced drive means for rotating at a predetermined speed according roll the required regardless of the rotational force transmission from the rotation force transmitting means, whereby it is intended to achieve the object.

[0018]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described below with reference to FIGS. Here, the same components as those in the above-described conventional example are denoted by the same reference numerals. The length marking device 1 shown in FIG. 1 includes a printing unit 3 for marking a strip length mark on the surface of a cable 2 to be printed at predetermined intervals, a company name and the like, and a movement of the cable 2 from a predetermined position. Measuring means 4 for continuously measuring the distance, that is, the length of the cable 2 to be printed, and taking-up means 5 for taking up the printing cable 2 at a predetermined linear velocity and sending it to a winding drum (not shown)
And a rotation control unit 8 for controlling the operation of the printing unit 3 based on the measuring unit information 2A from the measuring unit 4. Reference numeral 70 denotes a copy tape roll around which a copy tape is wound, and reference numeral 72 denotes a copy tape.

The printing means 3 includes a guide roll 6 which comes into contact with the printed cable 2 traveling in the direction of the arrow in the figure and a guide roll 6 which is provided alongside the guide roll 6 and rotates via a chain 35 as a rotational force transmitting means. And a print roll 7 having one drive control unit 9.

The printing roll 7 and the guide roll 6 each have a diameter D ₁ [mm] and a circumference πD ₁ of 1000 [mm]. A second drive control unit 19 for controlling connection / release is provided,
The print cable 2 is rotated by being urged by the running cable 2 to transmit a driving force to the print roll 7 via the chain 15.

The print roll 7 is coaxially provided with a first clutch mechanism 9 as a first drive control unit, and when the first clutch mechanism 9 is in the “disengaged state”, the print roll 7 is connected to the guide roll 6. A motor 50 is provided as forcible driving means having a function of rotating the print roll 7 at a speed higher than the rotation speed and setting the print roll 7 in the initial position. The first motor 50 is provided based on information from the rotation control unit 8. The clutch mechanism 9 is "directly connected" to the shaft and is driven to rotate by a predetermined amount. Then, the clutch mechanism 9 is automatically "released" from the shaft, and then the print roll 7 is rotated at a high speed. State. That is, after the print roll 7 has engraved the character string of the strip length n and the company name / product name by the action of the clutch mechanism 9, the printing roll 7 is required to accumulate the measuring value 1000 [mm] by the measuring roll 43. The print roll 7 is rotated at a high speed, rotated to the initial position, and waits until the next strip length engraving timing. This motor 50
During the rotational drive, the second clutch mechanism 19 as the second drive control unit of the guide roll 6 is "opened" with the shaft, so that the rotational force of the motor 50 is not transmitted to the guide roll 6. At other times, it is automatically "directly connected" to the shaft.

The printing roll 7 has an electrically heated first print engraving portion 21 for engraving a line count on the printed cable 2 at one point on the circumference, and a portion between the line engraved stamp and the line engraved mark. Printing section 21A for engraving the product name, company name, etc.
, [N] is engraved on the printed cable 2 every one rotation of the measuring roll 43, that is, every 1000 [mm]. It has the function to engrave the company name and product name [SWCC SHOWA 1990 0.4 × 200P].

The measuring means 4 includes guide rolls 41 arranged opposite to each other along the longitudinal direction on the cable 2 to be printed.
A measuring roll portion 40 composed of a measuring roll 43 that is put on the belt 4A and rotates on the belt 4A;
A second output of the measurement information (pulse signal) 2A to the rotation control unit 8 for each rotation amount of the measuring roll 43 from a predetermined position, that is, for every unit rotation amount (10 [mm] in this embodiment). And a pulse transmitter 45. The take-off means 5 sandwiches the cable to be printed 2 between guide rolls 51 and 52 around a belt 5A and guide rolls 53 and 54 around a belt 5B.
According to (38), the cable to be printed 2 is rotated in the direction of the arrow in the figure to move the printed cable 2 in the direction A in the figure in the linear velocity C (0 to 3 in this embodiment).
0 [m] / min).

As shown in the figure, the rotation control unit 8 is provided in the printing unit 3 and based on the scale information 2A,
The clutch engagement signal 7A is output to the first clutch mechanism 9 every 1000 [mm] of the gauge value.

Here, the overall operation of this embodiment will be described with reference to FIG. Note that the pickup means 5 has a linear velocity C = 10
At 000 [mm] / min, the cable to be printed 2 is taken off, and the printing roll 7 is in a state where the strip length n = 1 is imprinted.

First, the measuring means 4 sends the measuring information 2A to the rotation control section 8 (step 40). Next, the rotation control unit 8 counts the scale information 2A and measures the scale value 1000 [m
m], an "operation instruction signal" 7A for setting the first clutch mechanism 9 to the "directly connected state" is output (step 42). Then, based on this, the first clutch mechanism 9 is fixed to the shaft, drives the printing roll 7, and places the line length n = 2 and the character string [SWCC SHOWA 1990 0.
4 × 200P] (step 44). Then, the first
The clutch mechanism 9 of the position where the marking is completed, for example, “3 /
At the position "5 rotations", the printing roll 7 automatically becomes "open", and the motor 50 directly connected to the shaft rotates the printing roll 7 "2/5 rotation" at a speed faster than the guide roll 6 (step 46). Wait for state (Step 4
8). Thereafter, the process returns to step 40, and a series of operations is sequentially repeated.

Since the present embodiment is constructed as described above, the rotation speed of the print roll 7 is the same as the take-up speed (linear speed C) of the cable 2 to be printed. Even if the marks are arranged, the printing tape 72 does not easily break because "slipping" or the like does not occur between the thin printing tape 72 and the thin printing tape 72. Also, according to the experiment, as in the conventional example, the strip length stamp 1000
The error between [m] and the measured length 1000 [m] is 50 [m].
m] or less, which can be practically ignored.
Accurate strip lengths can be engraved, and long sequence characters such as high-quality product names and company names can be engraved.

[0028]

According to the present invention, as described above, according to the present invention, a stamp length is stamped on a cable to be printed at a position corresponding to a measured length, and the length of a product name, a company name, etc. It is possible to provide a length mark device capable of engraving a sequence of characters with high quality.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of a length mark device according to an embodiment of the present invention.

FIG. 2 is an explanatory flowchart showing the operation of the length mark device of FIG. 1;

FIG. 3 is a configuration diagram of a length mark device according to a conventional example.

FIG. 4 is an explanatory flowchart showing an operation of an operation control unit forming a part of FIG. 3;

FIG. 5 is an explanatory flowchart showing the operation of the length mark device of FIG. 3;

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Length mark device 2 ... Printed cable 3 ... Printing means 4 ... Measurement means 5 ... Pickup means 6 ... Guide roll 7 ... … Printing roll 8… rotation control unit 9… first drive control unit 19… second drive control unit 21… first print marking unit 50… forced driving unit 21A … Second printing and engraving part 2A …… Scale information 7A ……… Operation instruction signal

Continuation of the front page (56) References JP-A-3-225707 (JP, A) JP-A-59-94007 (JP, A) JP-A-57-207811 (JP, A) JP-A-56-12506 (JP, A) JP-A-55-39363 (JP, A) JP-A-55-39332 (JP, A) JP-A-48-95256 (JP, A) JP-A-48-50278 (JP, A) 2-32605 (JP, U) Japanese Utility Model 62-69326 (JP, U) Japanese Utility Model 59-176537 (JP, U) Japanese Utility Model Utility Model 56-9006 (JP, U) (58) Fields surveyed (Int. Cl. ⁷ , DB name) B41F 17/10 B41F 17/20 H01B 7/36

Claims (1)

(57) [Claims] A printing roll for engraving a predetermined length mark and a character string on a cable to be printed having a circumferential length as a unit printing interval length, and the printing roll following the movement of the printing roll and the cable to be printed. A printing means having a guide roll whose circumferential length to be driven is a unit printing interval length, and the printing means is provided on the take-up machine side to measure the movement amount of the cable to be printed and output the scale information. A length measuring device, and a length marking device comprising a take-up means for taking out the printed cable at a predetermined linear speed, wherein the shaft portions of the printing roll and the guide roll each have a shaft portion as necessary. A drive control unit for controlling the direct connection and release of the print roll is provided, and each drive control unit is connected via a rotational force transmitting means, and the print roll is rotated on the shaft of the print roll by the rotational force transmitting means. A length mark device comprising a forced drive means for rotating at a predetermined speed as necessary irrespective of force transmission.