JP5274153B2 - Tightening torque measurement unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a tightening torque measuring unit capable of discriminating the completion of a tightening work of one time by monitoring a peak torque value. <P>SOLUTION: This tightening torque measuring unit includes a torque sensor 12 for detecting tightening torque, a peak torque detection means 26 for detecting a peak torque value of an output torque value from the torque sensor 12, and a storage means 32 for storing the peak torque value detected by the peak torque detection means 26. The storage means 32 is capable of storing a plurality of torque values. The peak torque detection means 26 successively updates the peak torque value of the torque value, transmits the peak torque value to the storage means 32 and stores the value in the storage means 32, in the tightening work of one time. If the peak torque value is not updated for prescribed time or more, the tightening work is regarded to be completed, and the peak torque value is stored in the storage means 32. A torque value inputted next is determined to be a separate tightening work, a peak torque value is detected and the peak torque value is separately stored in the storage means 32. <P>COPYRIGHT: (C)2010,JPO&amp;INPIT

Description

  The present invention relates to a tightening torque measuring unit capable of detecting a tightening torque of a member to be tightened such as a bolt and a nut, and more specifically, stores a peak torque value or a waveform of the tightening torque. The present invention relates to a tightening torque detection unit having a storage means.

  There has been proposed a tightening torque detection unit capable of detecting a tightening torque when tightening a member to be tightened such as a bolt or a nut. Used to detachably attach to the power transmission mechanism of the machine.

  A tightening torque detection unit that can memorize the peak torque value of the measured torque value is also proposed, but after a single tightening operation is completed, a predetermined operation (for example, pressing a memory button) is performed. And once storing the peak torque value in the tightening operation, it is necessary to perform a new tightening operation.

JP 2007-1111797 A

  When performing continuous tightening work, it is troublesome to perform a predetermined operation to store the peak torque value for each tightening work, and if the operation is forgotten, the number of tightening operations performed and the stored peak There is also a problem that the number of torque values does not match.

  An object of the present invention is to provide a tightening torque measuring unit capable of determining completion of one tightening operation by monitoring a peak torque value.

In order to solve the above problems, the tightening torque measuring unit of the present invention includes:
A tightening torque measuring unit installed in a tightening machine,
A torque sensor for detecting a tightening torque, a peak torque detecting means for detecting a peak torque value of an output torque value from the torque sensor, and a storage means for storing a peak torque value detected by the peak torque detecting means; , And
The storage means can store a plurality of torque values,
The peak torque detecting means sequentially updates the peak torque value of the torque value in one tightening operation, transmits it to the storage means, and stores it. If the peak torque value is not updated for a predetermined time or more, the tightening is performed. Assuming that the work has been completed, the peak torque value is stored in the storage means, and the next input torque value is determined to be another tightening work, and the peak torque value is detected and stored separately in the storage means. Is.

The storage means stores the torque value input from the peak torque detection means in one tightening operation in the storage means. If the peak torque value is not updated for a predetermined time or more, the storage means Assuming that the tightening operation has been completed, it is desirable to separately store the torque value input from the next peak torque detection means in the storage means.

  The tightening torque measuring unit of the present invention can be detachably mounted on a driving unit of a tightening machine or a power transmission mechanism, for example, a rotary shaft, or can be integrally mounted by being incorporated in a driving part of the tightening machine. You can also

  Examples of the tightening machine that can be equipped with the tightening torque measuring unit of the present invention include an electric type, a hydraulically operated type, a compressed air operated type, and a manual wrench. .

According to the present invention, it is possible to store the peak torque value and / or the waveform of the torque value for each tightening operation.
The storage of the peak torque value and / or the waveform of the torque value is performed by paying attention to the fact that there is no update of the peak torque value during a predetermined time after moving to the next tightening operation after the completion of one tightening operation. Thus, the user can prevent omission of recording of the peak torque value of the torque value and / or the waveform of the torque value without requiring any special operation or the like.

  The tightening torque measuring unit (10) of the present invention stores a peak torque value and / or a waveform of a torque value for each tightening operation in a tightening operation of a bolt, a nut or the like using a tightening machine (not shown). It is something that can be done.

The present invention will be described below with reference to the drawings.
FIG. 1 shows a block diagram of a tightening torque measuring unit (10) of the present invention.
As shown in FIG. 1, the tightening torque measuring unit (10) mainly includes a torque sensor (12), torque measuring means (13) for converting an output from the torque sensor (12) into a torque value, Peak torque detection means (26) for detecting the peak torque value from the torque value measured by the torque measurement means (13), and the peak torque value set in advance by the peak torque detection means (26) Overload history storage means (36) for storing and displaying as overload history when the value is exceeded, and overload warning display means (38) are provided.
The torque measuring unit (10) operates upon receiving power from a battery (not shown) or the like.

  A strain gauge can be exemplified as the torque sensor (12), and the torque sensor (12) is a drive unit or a power transmission mechanism, for example, when the tightening machine is an electric type, a compressed air operation type, or a hydraulic operation type. It can be attached to the rotating shaft, and when the tightening machine is a manual wrench or screwdriver, it can be attached to the arm portion or the shaft portion or attached to a socket or the like.

  The output from the torque sensor (12) is converted into a torque value by the torque measuring means (13). The torque measuring means (13) amplifies the output from the torque sensor (12) with a gain (15), and performs an offset correction (15a), an amplifier (14), and A / D converts the output from the amplifier (14). / D converter (16) and amplifiers (40) and (42) incorporated in a microprocessor (MPU) (20).

The amplifiers (40) and (42) are a right-rotating amplifier (40) and a left-rotating amplifier (42), which have different gains depending on the tightening direction of the tightening machine. The analog values output from the torque sensor (12) and the amplifier (14) are corrected for differences between the left and right rotational directions. As shown in FIG. 1, the right rotation amplifier (40) adjusts the input digital signal by the right gain (41), and the left rotation amplifier (42) has a gain value different from that of the right gain (41). Adjust the input digital signal by gain (43). Switching between the right rotation amplifier (40) and the left rotation amplifier (42) is performed by a left / right selection switch (22) described later.
In addition, this invention is not limited to the structure which changes a gain according to the fastening direction on either side.

  As shown in FIG. 1, a zero point adjustment operation button (29) for performing zero point adjustment (29a) is provided on the input side of the right rotation amplifier (40) and the left rotation amplifier (42). Can do. By operating the zero point adjustment operation button (29) and performing the zero point adjustment (29a), the deviation of the zero point due to the drift of the torque sensor (12) or amplifier (14) due to temperature, humidity, etc. is reset. The no-load state before the measurement can be recognized as zero, and the display torque value of the display means (30) can be set to zero.

Also, the right gain (41) of the right rotation amplifier (40) and the left gain (43) of the left rotation amplifier (42) can be easily adjusted before teaching or during maintenance by teaching operation. It is desirable. Thus, for example, as shown in FIG. 1, a teaching operation button is applied to a digital signal output from the A / D converter (16) and input to the right rotation amplifier (40) or the left rotation amplifier (42). When (28) is operated, the right gain (41) and the left gain (43) can be stored so that a specific torque load is converted as a display of the measured value.
Specifically, a right-turn rated torque (for example, +800 Nm if the rated torque is 800 Nm) is applied to the tightening machine with the tightening torque measuring unit (10) attached, and teaching operation is performed in this state. By operating the button (28) and the torque conversion means (28a) connected to the teaching operation button (28), the torque measurement value on the right side of the tightening torque measurement unit (10) is the rated torque (in the example +800 Nm) ) Adjust the right gain (41) to be converted as Similarly, in the reverse rotation, the left rotation torque is applied and the teaching operation button (28) is operated in this state, so that the torque measurement value of the left rotation of the tightening torque measurement unit (10) becomes the rated torque ( In the case of the example, the left gain (43) is adjusted so as to be converted as -800 Nm). As a result, it is not necessary to precisely adjust the rated torque and torque display given to the tightening torque measuring unit (10), and adjustment before shipping and during maintenance can be easily performed.

  The torque measuring means (13) amplifies the current value input from the torque sensor (12) with a predetermined gain (15) by an amplifier (14), performs offset correction (15a), and an A / D converter Output to (16). The A / D converter (16) A / D converts the output from the amplifier (14), and the output from one of the amplifiers (40) and (42) switched by the left / right selection means (24) detects the peak torque. It is transmitted to the means (26).

  A right / left selection switch (22) is connected to the output side of the right rotation amplifier (40) and the left rotation amplifier (42). The left / right selection switch (22) is operated by the left / right selection means (24) for determining whether the tightening direction of the tightening machine is the right direction or the left direction, and the left / right selection means (24) is a right rotation. The left / right selection switch (22) is connected to the right rotation amplifier (40), and the left / right selection switch (22) is connected to the left rotation amplifier (42). Connect with. The details of the left / right discrimination by the left / right selection means (24) will be described with reference to the flowchart of FIG.

  The output from the right rotation amplifier (40) or the left rotation amplifier (42) is transmitted to the peak torque detection means (26) via the left / right selection switch (22). The peak torque detection means (26) detects the peak torque value and / or torque waveform of the detected torque value (step 9), and displays and stores it in the display means (30) and / or storage means (32) described later. Make them equal.

The peak torque detection means (26) is a torque value output from the torque measurement means (13), i.e., the right rotation amplifier (40) or the left rotation amplifier (42) in this embodiment (hereinafter referred to as `` current torque The peak torque value is detected from the “value”).
The peak torque detection means (26) compares a preset upper limit peak torque value with a current torque value, and when an overload torque value exceeding the upper limit peak torque value is input, an overload history storage means (36) And overload warning display means (38).

  A flash memory can be exemplified as the overload history storage means (36). The overload history storage means (36) stores the overload torque value exceeding the upper limit peak torque value as an overload history. Note that a plurality of overload torque values exceeding the upper limit peak torque value can be stored, or the date and time can be stored simultaneously.

  The overload warning display means (38) displays that an overload torque value exceeding the upper limit peak torque value has been detected. Examples of the overload warning display include “Error: OVER LOAD”.

  It is desirable that the overload history of the overload history storage means (36) and the overload warning display of the overload warning display means (38) cannot be deleted until maintenance is performed. The overload history and overload warning display can be deleted by the overload history release means (39), and the operation is executed only when the maintenance worker performs the maintenance of the tightening torque measurement unit (10). It is desirable to be able to do so.

The peak torque detecting means (26) may be used for displaying and storing the peak torque value in the tightening operation and storing the torque waveform in addition to the comparison between the above-described upper limit peak torque value and the current torque value. it can. The peak torque value in the tightening operation can be output to the peak torque value display means (30), and the peak torque value can be stored in the peak torque value storage means (32). The torque waveform can be stored in the torque waveform storage means (34).
The peak torque value display, storage, and torque waveform storage are desirably performed separately for each tightening operation as shown in flowcharts 2 and 3 described later.

  The operation of the tightening torque measuring unit (10) having the above-described configuration will be described with reference to flowcharts 2 and 3.

  When power is supplied to the tightening torque measuring unit (10), first, referring to whether or not the overload history is stored in step 14 to be described later (step 1), the overload history storage is executed. If an overload warning is detected, an overload warning is displayed on the overload warning display means (step 2).

  When the overload warning is displayed, there is a possibility that the torque measurement value is out of order, so it is desirable to promptly request maintenance of the torque measurement unit (10). By displaying the overload warning, the user or administrator can visually recognize the torque measurement unit (10) when using it.

  After judging the presence or absence of overload history, operate the zero adjustment button (29) and perform zero adjustment (29a) to reset the zero deviation of the torque sensor (12) and amplifier (14). (Step 3).

  To measure the torque, the left / right selector switch (22) is connected in advance to the right rotation amplifier (40) (step 4), and the output from the right rotation amplifier (40) exceeds a certain value. For example, when the display start torque value on the display means (30) set in advance becomes equal to or greater than (step 5), the left / right selection means (24) converts the output (digital value) torque conversion value ( Nm) is determined to be positive or negative, and if the torque conversion value is positive, it is determined that the tightening direction of the tightening machine is clockwise and negative if it is negative (step 6). If the result of the determination is right rotation, the left / right selection means (24) directly connects the left / right selection switch (22) to the right rotation amplifier (40) (step 7), and conversely, the determination is left rotation. If there is, the connection is switched to the left rotation amplifier (42) (step 8).

  The output from the right rotation amplifier (40) or the left rotation amplifier (42) is transmitted to the peak torque detection means (26) via the switch mechanism (22). The peak torque detection means (26) detects the peak torque value and / or torque waveform of the detected torque value (step 9), and displays and stores it in the display means (30) and / or storage means (32) described later. Make them equal.

FIG. 3 is a flowchart showing the operation of the peak torque detecting means (26), and shows step 9 in the flowchart of FIG. 2 in detail.
As shown in the flowchart of FIG. 3, the peak torque detection means (26) starts peak torque detection for the torque value output from the right rotation amplifier (40) or the left rotation amplifier (42) (step 21). .
For peak torque detection, the peak torque value stored in advance in the peak torque detection means (26) is cleared (step 22), and the peak torque value is calculated from the torque value input for a predetermined time (set to 1 second in FIG. 3). Is detected. The predetermined time is not limited to the illustrated one second, and can be set arbitrarily.
When a torque value is input to the peak torque detecting means (26) (step 24), the peak torque detecting means (26) records a torque waveform (step 25), and the input torque value (current torque value) is Then, it is determined whether or not it is larger than the peak torque value in the torque waveform. If the current torque value is larger than the stored peak torque value, the peak torque value is updated (step 27), and the predetermined time is counted again. Is started (step 28). If the current torque value is less than or equal to the stored peak torque value, step 24 to step 28 are repeated until a predetermined time has elapsed (step 29). In steps 24 to 28 that are repeated, every time the current torque value exceeds the original peak torque value, it is updated as a new peak torque value.

  If the peak torque value is not updated for a predetermined time (1 second in FIG. 3) or more, it is considered that the tightening operation has been completed, and the detection of the peak torque value and the recording of the torque waveform are completed (step 30). Proceed to step 10.

  The peak torque value detected by the peak torque detection means (26) is stored in the peak torque value storage means (32) as a peak torque value (step 10). The torque waveform is stored in the torque waveform storage means (34).

FIG. 4 is a diagram showing an example of a folder tree structure of the storage means that becomes the peak torque value storage means (32) and the torque waveform storage means (34). A microSD card (60) can be exemplified as the storage means, but is not limited to this.
As shown in FIG. 4, the microSD card (60) creates a folder (61) of the model name ("DTM8" in the figure) of the tightening torque measurement unit (10) as a folder tree structure, and the folder A folder (62) of the serial number ("0710003" in the figure) of the tightening torque measuring unit (10), and folders (63) and (64) of the date of the tightening operation are created under the folder (62). Data files are stored in the date folders (63) and (64), respectively.

In the data file stored in the date folder (63) (64), the peak torque value and the torque waveform detected in the flowchart of FIG. 3 in each tightening operation are shown for each tightening operation in the CSV (comma separated values) format. Can contain stored record rows. For example, the date folder (63) is obtained by performing only one group tightening operation on a corresponding day (November 13, 2007), and has only one CSV file. The date folder (64) stores a record of 100 group tightening operations as 100 CSV files.
The date folders (63) and (64) also contain the “LAST # GRP.TXT” file (65) and “LAST # TRQ.TXT” file that contain the last saved group file number and torque number. (66) is saved in text format.

  By monitoring the peak torque value as described above, the peak torque value and / or the torque waveform is stored for each tightening operation in the peak torque value storage means (32) without any special operation by the user. The reliability of torque tightening work can be improved. In addition, by storing the peak torque value and / or torque waveform for each tightening operation, the peak torque value and / or torque waveform can be easily confirmed later, and the peak torque value and / or The number of tightening operations can be confirmed from the number of torque waveforms (contents of the CSV file), and the collation operation with the number of tightening operations can be easily performed.

  In the above description, the peak torque value and the torque waveform are stored in one storage unit, but it is of course possible to divide the storage unit and folders. Furthermore, only one of the peak torque value and the torque waveform may be stored.

  Next, the peak torque detection means (26) compares the detected peak torque value with a preset upper limit peak torque value (step 11), and the peak torque value is smaller than the upper limit peak torque value. The detected peak torque value is displayed on the peak torque value display means (30) (step 12).

  On the other hand, if the peak torque value exceeds the upper limit peak torque value in step 11, an overload warning is displayed on the overload warning display means (38) (step 13) and an overload history storage means (36). ) Is stored with an overload torque value as an overload history (step 14).

  After the above is performed, the torque value storage position is advanced to the next work area in order to shift to the torque value measurement work in the next tightening work (step 15), and the process returns to step 3.

  According to the above, when a peak torque value exceeding the preset upper limit peak torque value is applied to the tightening torque measuring unit (10), it is stored as an overload history and is also displayed as an overload warning display. Therefore, the user can visually recognize that the tightening is out of specification, and can promptly request maintenance. In addition, there is an advantage that the maintenance worker can easily identify the abnormal part of the tightening torque measuring unit (10) by referring to the overload history during the maintenance.

  The present invention is useful as a tightening torque measurement unit capable of storing a peak torque value and / or a torque waveform for each tightening operation.

It is a block diagram of the tightening torque measuring unit of the present invention. It is a flowchart figure of the tightening torque measuring unit of this invention. It is a flowchart figure which shows the detection flow of a peak torque value and a torque waveform. It is a figure which shows the folder tree structure of a memory | storage means.

Explanation of symbols

(10) Tightening torque measurement unit
(12) Torque sensor
(20) Microprocessor
(26) Peak torque detection means
(32) Peak torque value storage means
(34) Torque waveform storage means
(36) Overload history storage means
(38) Overload warning display means

Claims (4)

A tightening torque measuring unit installed in a tightening machine,
A torque sensor for detecting a tightening torque, a peak torque detecting means for detecting a peak torque value of an output torque value from the torque sensor, and a storage means for storing a peak torque value detected by the peak torque detecting means; , And
The storage means can store a plurality of torque values,
The peak torque detecting means sequentially updates the peak torque value of the torque value in one tightening operation, transmits it to the storage means, and stores it. If the peak torque value is not updated for a predetermined time or more, the tightening is performed. Assuming that the work has been completed, the peak torque value is stored in the storage means, and the next input torque value is determined to be another tightening work, and the peak torque value is detected and stored separately in the storage means. Tightening torque measurement unit characterized by the above. Peak torque detection means in one tightening work, with Ru stored in the storage means as the waveform of the torque value of the torque value input from the peak torque detection means at predetermined time intervals, the current torque value, stored The peak torque value is updated by determining whether or not the torque value is greater than
Peak torque detection means, if there is no update of the predetermined time or more peak torque value, as the tightening operation is completed, stores the peak torque value in the storage means, the torque value input from the peak torque detection means to the next The tightening torque measuring unit according to claim 1, wherein the waveform is determined to be another tightening operation, and is stored in a separate storage unit and the peak torque value is updated . A tightening torque measuring unit installed in a tightening machine,
A torque sensor for detecting the tightening torque; peak torque detecting means for detecting an output torque value from the torque sensor; and storage means for storing the output torque value detected by the peak torque detecting means. And
The storage means can store a plurality of torque values,
The peak torque detecting means transmits the torque value input from the peak torque detecting means every predetermined time to the storage means as a torque value waveform and stores it in one tightening operation. If the value is not updated, it is determined that the tightening operation has been completed, the torque value waveform is stored in the storage means, and the next input torque value waveform is determined to be another tightening operation, A tightening torque measuring unit which is separately stored in a storage means. Tightening torque measuring unit according to any one of claims 1 to 3 is detachably mounted on the tightening device.

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