JPH07239229A - Method and device of pitch measurement for endless chain - Google Patents

Abstract

PURPOSE:To accurately measure the pitch of an endless chain by keeping it running. CONSTITUTION:To measure the pitch P between dogs 9 placed at every specific number of links 2, 3 of an endless chain 1 circulatingly running at a predetermined speed, the passage of the dogs 9 is detected with a photosensor 19 arranged in a circulation path of the endless chain 1. A sequencer 20 measures the time intervals T of passage of adjacent dogs 9 through the photosensor 19. A microcomputer 21 operates the pitch P by multiplying the time interval T by the velocity V of the endless chain 1 and operates the average value of P as the average of N times measurement. The operated average value of P is printed out of a printer 22.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and apparatus for measuring the pitch of an endless chain used in a conveyor or the like.

[0002]

2. Description of the Related Art An endless chain has a structure in which a large number of links are connected endlessly by pins, and when it is operated for a long time under a heavy load, the sliding parts between the pins and the links wear and the length increases. There is a problem that it grows. For example, in an endless chain used for a conveyor, when the pitch changes due to the wear, the meshing state with the sprocket may deteriorate or breakage may occur. Must be replaced when reaches a predetermined value.

Conventionally, in measuring the pitch of an endless chain of a conveyor, a worker uses a scale to measure the intervals between a plurality of dogs provided for a predetermined number of links while the conveyor is stopped.

As another method, two sensors for detecting the rollers of the endless chain are arranged along the traveling path of the endless chain of the conveyer, and the two sensors are arranged as the endless chain travels. It is known that pitch is measured based on the timing of detecting the roller (see Japanese Utility Model Laid-Open No. 58-17505).

[0005]

By the way, the former method has a problem that the efficiency and measurement accuracy for relying on the manual work of the worker are poor, and the line conveyor is greatly affected because it is necessary to stop the conveyor. There is.

The latter method described above can judge whether the pitch of the endless chain is proper or not, but the elongation rate of the endless chain cannot be known from a concrete numerical value, and the endless chain cannot be known. There is a problem that it is difficult to predict the lifespan of.

The present invention has been made in view of the above circumstances, and an object thereof is to easily and accurately measure the pitch of an endless chain.

[0008]

In order to achieve the above object, the invention described in claim 1 is an endless chain pitch measuring method for measuring the pitch of an endless chain circulating at a predetermined speed. It is characterized in that a time interval at which a plurality of detected parts provided for a predetermined number of constituent links passes is measured, and the distance between the detected parts is obtained by multiplying the time interval by the speed of the endless chain. .

The invention described in claim 2 is characterized in that, in addition to the configuration of claim 1, the distance between the detected portions is obtained a plurality of times and an average value thereof is calculated.

According to a third aspect of the present invention, there is provided an endless chain pitch measuring device for measuring the pitch of an endless chain circulating at a predetermined speed, wherein a plurality of cover members provided for every predetermined number of links constituting the endless chain. A detection unit, a detection unit that detects the passage of the detected unit and outputs a signal, a time measuring unit that detects the time interval of the output signal of the detection unit, and a running speed of the endless chain at the time interval detected by the time measuring unit. It is characterized in that it is provided with a calculating means for multiplying the distance between the detected parts and a display means for displaying a result calculated by the calculating means.

[0011]

Embodiments of the present invention will be described below with reference to the drawings.

1 to 4 show an embodiment of the present invention. FIG. 1 is a side view of a conveyer, and FIG. 2 is 2-2 of FIG.
A line sectional view, FIG. 3 is a diagram showing an output signal of the photosensor, and FIG. 4 is a flow chart for explaining the operation.

As shown in FIG. 1, a conveyor C that pulls and conveys a carriage D includes an endless chain 1 that is wound around a sprocket (not shown) and is circulated and driven along a predetermined path. The endless chain 1 has many first links 2 ...
And a large number of second links 3 ...
A structure in which the links 2 ... And the second links 3 ... Are pivotally supported by pins 4 ...

Brackets 5 are fixed to the upper surfaces of a predetermined number of first links 2 along the longitudinal direction of the endless chain 1 with two bolts 6 and 6, and two brackets are provided on each of the left and right side surfaces of the bracket 5. The guide rollers 7 ... Are supported via pins 8 and 8 and the dog 9 as a detected portion is supported via the pin 10 on the upper end of the bracket 5. Further, a bracket 11 is fixed to the upper surface of a predetermined number of second links 3 along the longitudinal direction of the endless chain 1 with one bolt 12, and one guide roller is provided on each of the left and right side surfaces of the bracket 11. 13, 13 are supported via pins 14.

The pair of left and right guide rails 16 and 16 laid on the lower surface of the floor 15 have the guide rollers 7 ...
3 are fitted together, whereby the endless chain 1 is guided along a predetermined path. Dog 9 provided on the bracket 5
Is projected upward between the pair of left and right guide rails 16 through a slit 17 formed in the floor 15. The dog 9 is engaged with the hook 18 so that the carriage D is pulled by the endless chain 1. To run.

A photo sensor 19 as a detecting means is provided at a predetermined position of the circulation path of the endless chain 1 so as to face the upper surfaces of the dogs 9 ... The photo sensor 19 is a dog 9 ...
The reflected light from the upper surface of the dog 9 is detected, and is turned "ON" when the front end of the dog 9 ... Passes, and is turned "OFF" when the rear end of the dog 9 ... Passes. Therefore, the photo sensor 19
Outputs a pulsed signal at the moment when the dogs 9 ... Pass (see FIG. 3). A sequencer 20 is connected to the photo sensor 19 as a time measuring means.
A microcomputer 21 as a calculation means is connected to 0, and a printer 22 as a display means is connected to the microcomputer 21.

Next, the operation of the embodiment of the present invention having the above-mentioned structure will be described with reference to the flowchart of FIG.

The conveyor C is driven to drive the endless chain 1
When a plurality of dogs 9 ... Are provided at a predetermined interval on the endless chain 1 when running, the photo sensors are sequentially arranged in the order of 1st dog 9, 2nd dog 9, 3rd dog 9, 4th dog 9 ... 19
, The photosensor 19 outputs the pulse signal shown in FIG. 3 to the sequencer 20 each time.

[ON] by the first dog 9 after starting the measurement
When the signal is output from the photo sensor 19 to the sequencer 20, the regular pitch P ₀ (the pitch between the pair of adjacent dogs 9, 9 when the endless chain 1 is not worn at all, which is stored in advance in the sequencer 20, 1) is output to the microcomputer 21 (step S).
1). Then, when the “OFF” signal from the first dog 9 is output from the photo sensor 19 to the sequencer 20, the sequencer 20 starts measurement of a time interval T = T ₁₂ described later.

Subsequently, when the "ON" signal from the second dog 9 is output from the photo sensor 19 to the sequencer 20,
The sequencer 20 sends the "OFF" signal from the first dog 9 and 2
The time interval T ₁₂ with the “ON” signal by the watch dog 9 is measured and output to the microcomputer 21. The microcomputer 21 calculates the actual pitch P = P ₁₂ between the first dog 9 and the second dog 9 by multiplying the time interval T ₁₂ by the transport speed V (constant) of the transport conveyor C (step S2), This actual pitch P ₁₂ and the regular pitch P
The average value of ₀ is calculated (step S3). When the “OFF” signal from the second dog 9 is output from the photo sensor 19 to the sequencer 20, the sequencer 20 starts measuring the time interval T ₂₃ .

Subsequently, when an "ON" signal from the third dog 9 is output from the photo sensor 19 to the sequencer 20,
The sequencer 20 receives the "OFF" signal from the second dog 9 and 3
The time interval T ₂₃ with the “ON” signal by the watch dog 9 is measured and output to the microcomputer 21. Conveying speed V microcomputer 21 in the time interval T ₂₃
The actual pitch P ₂₃ between the second dog 9 and the third dog 9 is calculated by multiplying by, and the average value of the actual pitch P ₁₂ and the regular pitch P ₀ is calculated. "OF of 3 by dog 9"
When F "signals is output sequencer 20 from the photosensor 19, the sequencer 20 starts the time interval T _34.

When all the pitches between the dogs 9 are measured by repeating the above operation while the endless chain 1 circulates once, the first dog 9 to the second dog 9 are measured in the same manner as the first measurement described above. Start. In the second measurement, the average value of the stored first average value and the second actual pitch P = P ₁₂ , P ₂₃ , P ₃₄ ...
The pitch between the first dog 9 and the second dog 9, the pitch between the second dog 9 and the third dog 9, the pitch between the third dog 9 and the fourth dog 9, ... Are respectively calculated.

By repeating the above operation N times, when the average value of N times of the pitches between all dogs 9 ... Of the endless chain 1 is calculated (step S4), all dogs 9 are calculated.
It is determined whether or not the elongation rate of the final average value with respect to the regular pitch P ₀ is 3% or more with respect to the pitch between ... (step S5), and if the elongation rate is 3% or more, an abnormality is determined and (Step S6) If it is less than 3%, it is determined to be normal (step S7). Then, the measurement result is output from the printer 22 connected to the microcomputer 21, and based on the result of printing out, it is possible to accurately replace the worn part and predict the life of the endless chain 1.

As described above, the pitch between the dogs 9 of the endless chain 1 can be automatically measured without depending on the manual work of the operator, and further, it is not necessary to stop the conveyor C at the time of measurement. The effect on the line can be minimized. Further, since the average value of the measurement results of a plurality of times is obtained, it is possible to perform a precise measurement with a small error, and it is possible to accurately grasp the degree of wear of the endless chain 1, and moreover, what dog 9 and what number. By knowing whether the pitch between the dogs 9 is abnormal, the portion can be repaired.

Although the embodiments of the present invention have been described in detail above, the present invention is not limited to the above embodiments, and various design changes can be made.

For example, it is possible to use something other than the dog 9 as the detected portion, and as shown in FIG. 1, a mark 23 that can be detected by the photosensor 19 is provided on each predetermined number of links 3. It can be provided at the end of the rotation shaft of the guide roller 7. Further, the detection means is the photo sensor 1
The number of switches is not limited to 9, and various proximity switches and limit switches can be used. Also, as display means,
A CRT or LED may be used instead of the printer 22. In the embodiment, the endless chain 1 of the conveyor C is also used.
However, the present invention can be applied to endless chains for other applications.

[0027]

As described above, according to the invention described in claim 1, the time intervals at which a plurality of detected parts provided for each predetermined number of links constituting the endless chain pass are measured and the time is measured. Since the distance is detected by multiplying the interval by the speed of the endless chain to obtain the distance between the detected portions, pitch measurement can be performed without depending on the manual work of the worker and without stopping the endless chain. Moreover, since the pitch can be measured as a specific numerical value, the degree of wear of the endless chain can be surely grasped and the maintenance and the replacement timing can be accurately managed.

According to the invention described in claim 2,
Since the distance between the detected parts is obtained a plurality of times and the average value thereof is calculated, it is possible to perform precise measurement with a small error.

According to the invention described in claim 3,
A plurality of detected parts provided for every predetermined number of links constituting the endless chain, a detecting means for detecting passage of the detected parts and outputting a signal, and a time measuring means for detecting a time interval of the output signal of the detecting means. Since the time interval detected by the time measuring means is multiplied by the traveling speed of the endless chain to obtain the distance between the detected parts, and the display means for displaying the result calculated by the calculating means are provided. Not only can the pitch be automatically measured without stopping the chain,
Since the pitch can be known as a specific numerical value, the degree of wear of the endless chain can be reliably grasped, the maintenance and replacement timing can be accurately controlled, and the measurement result is displayed on the display means. Data can be easily managed.

[Brief description of drawings]

[Figure 1] Side view of the conveyor

FIG. 2 is a sectional view taken along line 2-2 of FIG.

FIG. 3 is a diagram showing an output signal of a photo sensor.

FIG. 4 is a flowchart explaining the operation.

[Explanation of symbols]

 1 Endless Chain 2 First Link (Link) 3 Second Link (Link) 9 Dog (Detected Part) 19 Photo Sensor (Detecting Means) 20 Sequencer (Time Measuring Means) 21 Microcomputer (Calculating Means) 22 Printer (Display Means) 23 mark (detected part)

Claims (3)

[Claims] 1. An endless chain (1) circulating at a predetermined speed.
In a pitch measuring method for an endless chain for measuring the pitch of a plurality of detected parts (9, 23) provided for a predetermined number of links (2, 3) forming the endless chain (1), a time interval ( T) is measured, and the time interval (T) is multiplied by the speed (V) of the endless chain (1) to obtain a distance (P) between the detected parts (9, 23). Endless chain pitch measurement method. 2. The pitch measuring method for an endless chain according to claim 1, wherein the distance (P) between the detected parts (9) is obtained a plurality of times and an average value thereof is calculated. 3. An endless chain (1) circulating at a predetermined speed.
In a pitch measuring device for an endless chain for measuring the pitch of a plurality of detected parts (9, 23) provided for each predetermined number of links (2, 3) constituting the endless chain (1), Detection means (19) for detecting the passage of the signal (9, 23) and outputting a signal, a time measuring means (20) for detecting the time interval (T) of the output signal of the detecting means (19), and a time measuring means (2).
Calculation means (21) for calculating the distance (P) between the detected parts (9, 23) by multiplying the time interval (T) detected in 0) by the speed (V) of the endless chain (1); Means (2
A pitch measuring device for an endless chain, comprising a display means (22) for displaying the result calculated in 1).