KR20090036434A - Tape measure - Google Patents

Abstract

A measuring tape is provided to control the rewind speed of the tape accurately by applying the frictional force. A measuring tape comprises a case(10) which includes an inlet, a reel(30) which is mounted inside the case pivotally, a spiral spring(40) which rotates the reel at the opposite direction with the elastic restoring force, a tape(50) which is wound to the initial position according to the exterior of reel in the maximum diameter, a turning member(60) which has the other end(64) crossing the tape wound in the maximum diameter, an elastic member(80) which turns the other end of the turning member with the elastic restoring force to the tape, and operation means(90) mounted on the case.

Description

Tape Measure {TAPE MEASURE}

The present invention relates to a tape measure, and more particularly, to a tape measure capable of controlling the rewinding speed of a tape by a frictional force.

Tape measure is widely used to measure length. Tape tape uses a lot of steel tape and stainless steel tape for precise measurement. The tape is mounted inside the case so that the reel, which is wound with steel tape, can be rotated, and the spiral has elastic restoring force to rotate the reel in the winding direction of the steel tape in the center of the reel. It is equipped with a spiral spring. A hook is attached to the tip of the steel tape which is pushed out through the inlet of the case, and the hook can be fixed to the object under test.

When the user holds the case by hand while the hook is fixed to the object under test, the user moves by holding the case in a straight line from the object under test. As the steel tape is pulled out, the spiral spring is wound to increase the elastic restoring force. On the other hand, if the user releases the hook from the object under measurement after completing the measurement, the spiral spring is released by the elastic restoring force to rotate the reel, the steel tape is wound on the outer surface of the rotating reel. When the hook is caught at the entrance of the case and the reel stops rotating, the steel tape is completely received inside the case.

U.S. Patents 6,673,182 and 6,90809 disclose a technique employing a braking device to control the rewinding of a steel tape. The technique of these patent documents is configured such that when the brake is operated by the operation of the knob Knob exposed on the outer surface of the case, the brake contacts the steel tape and restrains the rewinding of the steel tape.

However, the tape measure of the above-mentioned patent documents shows that in the rewinding operation of the steel tape drawn out from the case, the speed of the steel tape rewinding by the elastic restoring force of the spiral spring is very fast, and the fast-moving hook hits the case and has a strong impact. There is a problem of causing a breakage of the case and deformation of the hook. In particular, there is a problem that a safety accident in which the user's hand is in contact with the edge of the steel tape (Edge) or hit by a hook and injured is often caused.

In order to reduce the rewinding speed of the steel tape, the elastic resilience force of the spiral spring may be made small. However, when the elastic restoring force of the spiral spring is small, the rewinding speed of the steel tape is too slow to delay the measurement time, and there is a problem that the steel tape does not completely rewind to the reel and stops.

On the other hand, the brake device of the above patent documents is operated to completely stop the rewinding of the steel tape by the user's operation. Therefore, in order to control the rewinding speed of the steel tape by the brake device, there is a very troublesome and inconvenient problem that the user must repeatedly operate the brake device several times.

The present invention has been made to solve the various problems of the prior art as described above, the object of the present invention is to give a friction force to the tape rewinding through the inlet of the case tape measure that can control the rewinding speed of the tape In providing.

Another object of the present invention is to provide a smooth tape measure while the tape unwinding operation can be controlled while rewinding speed of the tape.

Still another object of the present invention is to provide a tape measure which can greatly improve safety by self-locking, in which a rewinding tape is automatically stopped.

It is still another object of the present invention to provide a tape measure which can be easily released by releasing a state in which the tape is stopped during rewinding.

Features of the present invention for achieving the above object, the case is formed with an inlet on one side; A reel mounted to rotate inside the case; A spiral spring having one end fixed to the case and the other end fixed to the reel, and the reel rotating in one direction when the reel is rotated in one direction; A rear end is fixedly wound on the outer surface of the reel, the leading end is drawn out through the inlet of the case, and is wound on the outer surface of the reel with a maximum diameter at an initial position; A rotating member mounted inside the case so as to be rotated, the rotating member being disposed so that the other end intersects the tape wound at the maximum diameter; An elastic member mounted to the case such that the other end of the rotation member is rotated in a direction toward the tape by the elastic restoring force; The other end of the rotating member is on a tape measure including operating means mounted to the case to press the rotating member in the direction away from the tape.

Other objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and preferred embodiments associated with the accompanying drawings.

Hereinafter, preferred embodiments of the tape measure according to the present invention will be described in detail with reference to the accompanying drawings.

1 to 7 an embodiment of a tape measure according to the invention is shown. 1 and 2, the tape measure of the present invention includes a case 10 constituting an appearance. The case 10 is composed of a left case 12 and a right case 14 which can be separated from left and right. The left case 12 and the right case 14 are firmly assembled by fastening the plurality of screws 16. An inlet 18 is formed below one side of the case 10. The boss 20 is formed at the center of the inner surface of the left case 12, and a pair of shaft holes 22a and 22b are formed to face one side of the inner surfaces of the left and right cases 12 and 14. The hole 24 is formed in one side of the case 10 in the opposite direction to the inlet 18.

1 to 3, the reel 30 is mounted inside the case 10 so as to rotate. Bore 32 is formed in the center of the reel 30, the boss 20 of the case 10, the spiral spring 40 having an elastic restoring force is formed in the bore 32 of the reel 30 It is installed. One end of the spiral spring 40 is fixed to the boss 28 of the case 10 and the other end is fixed to the inner surface of the reel 30. A cover 42 covering the bore 32 is mounted on one side of the reel 30 to prevent the spiral spring 40 from being separated from the bore 32. The elastic restoring force of the spiral spring 40 acts to return to the initial position by rotating the reel 30 in one direction in the opposite direction.

In addition, a flexible tape 50, for example a steel tape, is wound in a roll type on the outer surface of the reel 30. The rear end of the tape 50 is fixed to the reel 30 and the front end is drawn out through the inlet 22 of the case 10. The tape 50 is released from the reel 30 by rotating the reel 30 in one direction, and wound on the reel 30 by rotating the reel 30 in the other direction. A scale 52 for measuring the length along the longitudinal direction is indicated on the surface of the tape 50. The tip of the tape 50 becomes the zero point of length measurement.

A hook 54 is attached to the front end of the tape 50 which is pulled out through the inlet 22 of the case 10. The user can pull the hook 54 to pull out the tape 50 or hang it on the object 2 to measure the length. As shown in FIGS. 3 and 4, the tape 50 is wound on the outer surface of the reel 30 at the initial position of the tape 50 on which the hook 54 hangs at the inlet 22 of the case 10. The first diameter D1 of becomes the maximum diameter.

1 to 4, one end 62 of the rotation member 60 is mounted inside the case 10 so as to rotate. The other end 64 of the rotation member 60 is disposed so as to intersect with the tape 50 wound around the first diameter D1. The other end 64 of the rotating member 60 arranged to intersect with the tape 50 is in contact with the tape 50 wound on the reel 30. A shaft 66 is formed at one end 62 of the rotation member 60, and the shaft 66 is fitted to rotate in the shaft holes 22a and 22b of the case 10. The groove 68 is formed in the other end 64 of the rotation member 60.

The other end 64 of the rotating member 60 is further provided with a friction member 70 for contacting the tape 50 wound on the reel 30 at the initial position of the tape 50 to impart a frictional force. The friction member 70 is composed of a friction pad 72 that is fixedly coupled to the groove 68 of the rotation member 60. The friction pad 72 is in contact with the back surface of the tape 50 to apply a friction force to control the rewinding of the tape 50. The friction pad 72 may be attached to the other end 64 of the rotation member 60 by the adhesive. The friction pad 72 may be made of rubber, synthetic rubber, silicon rubber, silicon rubber, or the like.

An elastic member 80 is attached to the shaft 66 of the rotating member 60 to rotate the rotating member 60 by an elastic restoring force in a direction in which the friction member 70 contacts the rear surface of the tape 50. The elastic member 80 may be composed of a torsion spring (Torsion Spring: 82), a compression coil spring and the like. One end of the torsion spring 82 is mounted to the inner surface of the case 10 and the other end is mounted to the rotation member 60. One end of the compression coil spring may be mounted to one side or the shaft 66 of the rotating member 60 and the other end to the inner surface of the case 10.

1 to 6, the tape measure of the present invention includes an operation mechanism 90 for pressing and rotating the rotating member 60. The operating mechanism 90 is composed of a push button 92, a spring 94, and a stopper 96. The push button 92 is composed of a button portion 92a and a rod portion 92b. The button portion 92 is disposed outside the case 10 so that the user can operate it. The rod part 92b penetrates through the case 10 so that the friction member 70 can push and rotate the rotation member 60 in the direction away from the tape 50. The spring 94 is mounted between the outer surface of the case 10 and the button portion 92 of the push button 92, and provides an elastic force to return the push button 92 to the initial position. The spring 94 may be composed of a compression coil spring. The stopper 96 is mounted to the rod portion 92b of the pushbutton 92 located inside the case 10 and contacts the inner surface of the case 10 to restrain the initial position of the pushbutton 92. do. The stopper 96 may be configured as a snap ring.

Tape measure of the present invention is provided with a stopper 100 as a restraining means for restraining the rotation of the rotation member 60 on one side of the inner surface of the case (10). The stopper 100 may be integrally formed with the case 10 which is injection molded from plastic. At the initial position of the tape 50 where the friction member 70 is in contact with the back surface of the tape 50, the rotation member 60 interferes with the stopper 100, and thus the rotation of the rotation member 60 is constrained.

As shown in FIGS. 3 and 4, the friction member 70 is positioned on the outer surface of the tape 50 at the initial position of the tape 50 where the hook 54 hangs on the inlet 22 of the case 10. Contact to give friction. As the tape 50 is released from the reel 30 in the initial position, the first diameter D1 of the tape 50 gradually decreases at the maximum size, and the first diameter D of the tape 50 decreases. As a result, the friction force between the tape 50 and the friction member 70 is gradually reduced.

As shown in FIG. 5, the friction member is released when the tape 50 is released from the reel 30 at an initial position by the user pulling the tip of the tape 50 from the inlet 18 of the case 10. The torque 70 is given torque by the frictional force with the tape 50, and the rotating member 60 is rotated about the shaft 66 by the torque applied to the friction member 70. Thus, the friction force between the tape 50 and the friction member 70 is reduced, and the tape 50 is smoothly released from the reel 30.

On the other hand, when the tape 50 is pulled out from the point P at which contact with the friction member 70 starts, at the first length L1, the tape 50 and the friction member 70 are in continuous contact. At this time, the tape 50 continuously in contact with the friction member 70 is wound on the outer surface of the reel 30 to the size of the second diameter (D2) or more.

As shown in FIG. 6, when the tape 50 is drawn out beyond the second length L2 from the point P at which the tape 50 is in contact with the friction member 70, the tape 50 and the friction member ( 70 is contactless. At this time, the tape 50 which is not in contact with the friction member 70 is wound on the outer surface of the reel 30 to a size less than the third diameter (D3). The tape 50 is drawn out beyond the second length L2 which is not in contact with the friction member 70 and rewinds to be in contact with the friction member 70 by a gradual increase in diameter. When the tape 50 is brought into contact with the friction member 70 during the rewinding operation of the tape 50 in this manner, the rewinding speed of the tape 50 is reduced by frictional contact with the friction member 70.

The following describes the operation of the tape measure according to the present invention having such a configuration.

Referring to FIGS. 3 and 5, the user hangs and secures the hook 54 to the object to be measured 2, and moves by holding the case 10 to form a straight line from the point where the hook 54 is fixed. As the user moves, the tape 50 wound on the reel 30 is pulled through the inlet 22 of the case 10.

Due to the pulling force of the tape 50, the reel 30 is rotated in one direction, that is, clockwise as shown by arrow "A" in FIG. 3, and the tape 50 is pulled out by the rotation of the reel 30. While being drawn out through the inlet 22 of the case (10). As the spiral spring 40 is wound in a clockwise direction with the rotation of the reel 30, the elastic restoring force of the spiral spring 40 is accumulated, and the elastic restoring force of the spiral spring 40 is proportional to the unwinding length of the tape 50. Is increased.

Referring to FIG. 4, the friction member 70 is in contact with the outer surface of the tape 50 at the initial position of the tape 50 where the hook 54 is caught by the inlet 22 of the case 10. When the tape 50 is released from the reel 30, the friction member 70 is torqued by the frictional force with the tape 50 released, and the rotating member 60 by the torque applied to the friction member 70. ) Rotates in the opposite direction to the reel 30, that is, counterclockwise, as shown by arrow "B" in FIG. Thus, the friction force between the tape 50 and the friction member 70 is reduced, and the tape 50 is smoothly released from the reel 30. The elastic restoring force of the torsion spring 82 is accumulated by the counterclockwise rotation of the rotation member 60. On the other hand, as the tape 50 is released from the reel 30, the first diameter D1 of the tape 50 gradually decreases, and the friction force between the tape 50 and the friction member 70 also gradually decreases. The tape 50 is smoothly released from the reel 30.

As shown in FIG. 6, when the tape 50 is drawn out beyond the second length L2 and wound around the outer surface of the reel 30 to the third diameter D3, the tape 50 and the friction member ( 70) are not contacted. When the tape 50 and the friction member 70 are not in contact, the rotation member 60 is rotated clockwise by the elastic restoring force of the torsion spring 82, as shown by the arrow "C" in FIG. The rotating member 60 rotated clockwise is supported by the stopper 100 and restrained.

After the user measures the length of the subject 2 by drawing the tape 50, the user releases the hook 60 from the subject 2. When the latched state of the hook 60 is released, the spiral spring 40 is released in the counterclockwise direction in the wound state by the elastic restoring force. The reel 30 is also rotated counterclockwise by the release operation of the spiral spring 40, and the tape 50 is wound around the outer surface of the reel 30 being rotated. When the tape 50 is not in contact with the friction member 70 in the rewinding process, the rewinding of the tape 50 is performed at a high speed in proportion to the elastic restoring force of the spiral spring 40.

As shown in FIG. 5, when the rewinding tape 50 is wound on the outer surface of the reel 30 with the second diameter D2, the friction member 70 returns to the rear surface and the initial position of the tape 50. Contact is started. Therefore, the tape 50 is given the frictional force of the friction member 70, and the rewinding speed of the tape 50 is reduced. Since the tape 50 receives the friction force continuously from the time when the contact with the friction member 70 starts, the rewinding speed of the tape 50 is rapidly reduced from the time when the contact with the friction member 70 starts. Therefore, the rewinding of the tape 50 is performed safely and accurately. In addition, breakage of the case 10 and deformation of the hook 54 that occurred when the hook 54 hits the case 10 are prevented, and injuries caused by the user's finger coming into contact with the tape 50 are prevented.

3 and 4, as the diameter of the rewinding tape 50 approaches the first diameter D1, the friction force between the tape 50 and the friction member 70 increases. If the frictional force between the tape 50 and the friction member 70 is greater than the elastic restoring force of the spiral spring 40, the rotation of the reel 30 and the rewinding of the tape 50 are stopped.

Referring to FIG. 7, when the rewinding of the tape 50 is stopped by the frictional force of the friction member 70, when the user presses the button portion 92a of the push button 92, the rod portion 92b is in an initial position. The rotating member 60 is pushed, and the rotating member 60 is rotated counterclockwise as shown by arrow "D" in FIG. When the rotating member 60 is rotated in the counterclockwise direction, the friction member 70 is spaced apart from the back surface of the tape 50, and the contact between the tape 50 and the friction member 70 is released. When the contact between the tape 50 and the friction member 70 is released, the reel 30 which is stopped by the elastic restoring force of the spiral spring 40 starts to rotate again, and the tape on the outer surface of the reel 30 rotated. 50 is wound up. Therefore, the tape 50 can be rewound easily and safely. When the user removes the force that pressed the button portion 92a of the push button 92, the push button 92 is returned to the initial position by the elastic restoring force of the spring 94.

8 and 9 show another embodiment of the restraining means for restraining the rotation of the rotating member in the tape measure of the present invention. 8 and 9, the restraining means of another embodiment includes a protrusion 102, a groove 104, a first locking jaw 106, and a second locking jaw 108. The protrusion 102 is formed on one side of the outer surface of the shaft 66. The groove 104 is formed to receive the projection 102 in the shaft hole 22a among the shaft holes 22a and 22b. The first catching jaw 106 and the second catching jaw 108 are formed so that the protrusions 102 may interfere with one side and the other side of the groove 104.

When the protrusion 102 interferes with the first locking step 106, the friction member 70 contacts the outer surface of the tape 50 at the initial position of the tape 50 to impart friction force. When the rotating member 60 is rotated about the shaft 66, the protrusion 102 moves along the groove 104. When the protrusion 102 is caught by the second locking jaw 108, the friction member 70 is in a release position spaced apart from the back surface of the tape 50. Constraining means consisting of the projection 102, the groove (Groove) 104, the first locking jaw 106 and the second locking jaw 108 to restrain the rotation of the rotation member 60 has a structure compared to the stopper 100 Can improve the productivity of the tape measure and reduce the production cost.

10 to 15 show a second embodiment of a tape measure according to the invention. In the tape measure of the second embodiment, the same configuration as that of the tape measure of one embodiment is given the same reference numeral, and detailed description thereof will be omitted. 10 to 12, the friction member 170 is mounted to the other end 64 of the rotation member 60. The friction member 170 is composed of a friction roller 172, the shaft 174 of the friction roller 172 is mounted so as to rotate on the other end 64 of the rotation member (60). The friction roller 172 is in contact with the back surface of the tape 50 to apply a friction force to control the rewinding of the tape 50. The friction roller 172 may be made of rubber, synthetic rubber, silicone rubber, urethane rubber, or the like.

The tape measure of the second embodiment includes a stopper 200 as a restraining means for restraining the rotation of the rotation member 60 on one side of the inner surface of the case 10. The stopper 200 is in contact with the outer surface of the friction roller 172 to restrain the rotation of the rotation member 60 and at the same time restrain the rotation of the friction roller 172. The stopper 200 may be integrally formed with the case 10 that is injection molded from plastic. At the initial position of the tape 50 where the friction roller 172 is in contact with the back surface of the tape 50, the friction roller 172 interferes with the stopper 200, thereby constraining the rotation of the rotation member 60. The stopper 200 may be disposed to be in contact with the rotation member 60 as necessary.

As shown in FIGS. 11 and 12, the friction roller 172 is positioned on the outer surface of the tape 50 at the initial position of the tape 50 where the hook 54 hangs on the inlet 22 of the case 10. Contact to give friction. As the tape 50 is released from the reel 30 in the initial position, the first diameter D1 of the tape 50 gradually decreases at the maximum size, and the first diameter D of the tape 50 decreases. As a result, the friction force between the tape 50 and the friction roller 172 is gradually reduced.

As shown in Fig. 13, when the user pulls the tip of the tape 50 from the inlet 18 of the case 10, the friction roller is released from the reel 30 in the initial position. The torque 172 is given torque by the frictional force with the tape 50, and the rotation member 60 is rotated about the shaft 66 by the torque applied to the friction roller 172. Therefore, the friction force between the tape 50 and the friction roller 172 is reduced, and the tape 50 is smoothly released from the reel 30. When the tape 50 is withdrawn to the first length L1 from the point P at which contact with the friction roller 172 starts, the tape 50 and the friction roller 172 are in continuous contact. At this time, the tape 50 continuously in contact with the friction roller 172 is wound on the outer surface of the reel 30 to the size of the second diameter (D2) or more.

As shown in FIG. 14, when the tape 50 is pulled out from the point P at which contact with the friction roller 172 starts, the tape 50 and the friction roller ( 172 is contactless. At this time, the tape 50 which is not in contact with the friction roller 172 is wound on the outer surface of the reel 30 to a size less than the third diameter (D3). The tape 50 is drawn out beyond the second length L2, which is not in contact with the friction roller 172, and then rewinds to contact the friction roller 172 by a gradual increase in diameter. When the tape 50 comes into contact with the friction roller 172 during the rewinding operation of the tape 50 in this manner, the rewinding speed of the tape 50 is reduced by the frictional contact with the friction roller 172.

Referring to FIG. 15, when the rewinding of the tape 50 is stopped by the frictional force of the friction roller 172, when the user presses the button portion 92a of the push button 92, the rod portion 92b is in an initial position. The rotating member 60 is pushed, and the rotating member 60 is rotated counterclockwise as shown by arrow "D" in FIG. When the rotating member 60 is rotated counterclockwise, the friction roller 172 is spaced apart from the back surface of the tape 50, and the contact between the tape 50 and the friction roller 172 is released. When the contact between the tape 50 and the friction roller 172 is released, the reel 30 which is stopped by the elastic restoring force of the spiral spring 40 starts to rotate again, and the tape on the outer surface of the reel 30 rotated. 50 is wound up. Therefore, the tape 50 can be rewound easily and safely. When the user removes the force that pressed the button portion 92a of the push button 92, the push button 92 is returned to the initial position by the elastic restoring force of the spring 94.

The embodiments described above are merely illustrative of the preferred embodiments of the present invention, the scope of the present invention is not limited to the described embodiments, those skilled in the art within the spirit and claims of the present invention It will be understood that various changes, modifications, or substitutions may be made thereto, and such embodiments are to be understood as being within the scope of the present invention.

As described above, according to the tape measure according to the present invention, the tape rewinding through the inlet of the case may be given a frictional force by the contact of the friction member to safely and accurately control the rewinding speed of the tape. In addition, while the tape rewinding speed can be controlled, the tape unwinding operation can be smoothly performed, and the safety can be greatly improved by self-locking which is automatically stopped during the tape rewinding.

1 is a perspective view showing an embodiment of a tape measure according to the present invention,

2 is a perspective view separately showing the configuration of a tape measure according to the present invention;

Figure 3 is a front view showing the inside of the left case showing the right case separated from the tape measure of the present invention,

4 is a cross-sectional view partially showing a configuration in which the tape and the friction member is in contact with the tape measure of the present invention;

5 is a cross-sectional view partially showing a configuration in which a tape is drawn out to a first length in continuous tape contact with a friction member in the tape measure of the present invention;

6 is a cross-sectional view partially showing a configuration in which a tape is drawn out to a second length at which non-contact with a friction member starts in a tape measure of the present invention;

7 is a partial cross-sectional view for explaining the operation of the operating mechanism in the tape measure of the present invention,

8 is a perspective view partially showing another embodiment of the restraining means in the tape measure of the present invention;

9 is a partial cross-sectional view showing another embodiment of the restraining means in a tape measure of the present invention;

10 is a perspective view separately showing the configuration of the second embodiment of the tape measure according to the present invention;

Figure 11 is a front view showing the inside of the left case showing the right case separated from the tape measure of the second embodiment according to the present invention,

12 is a partial cross-sectional view showing a configuration in which the tape and the friction member is in contact with the tape measure of the second embodiment according to the present invention;

13 is a cross-sectional view partially showing a configuration in which a tape is drawn out to a first length in continuous tape contact with a friction member in a tape measure of a second embodiment according to the present invention;

14 is a cross-sectional view partially showing a configuration in which a tape is drawn out to a second length at which a non-contact with a friction member is started in a tape measure of a second embodiment according to the present invention;

15 is a partial cross-sectional view for explaining the operation of the operating mechanism in the tape measure of the second embodiment according to the present invention.

♣ Explanation of symbols for the main parts of the drawing ♣

10: Case 18: Boss

22a, 22b: Axial hole 30: Reel

40: spiral spring 50: tape

60: rotating member 62: first

64: other end 66: shaft

68: groove 70, 170: friction member

72: friction pad 80: elastic member

82: torsion spring 90: operating mechanism

92: pushbutton 94: spring

100, 200: stopper 102: projection

104: groove 106: first locking jaw

108: second locking jaw 172: friction roller

Claims (9)

A case having an inlet formed on one side thereof; A reel mounted to rotate inside the case; A spiral spring having one end fixed to the case, the other end fixed to the reel, and the reel rotating in the opposite direction by the elastic restoring force when the reel is rotated in one direction; A tape having a rear end fixed to the outer surface of the reel, the leading end being drawn out through an inlet of the case, and wound around the outer surface of the reel with a maximum diameter at an initial position; A rotating member mounted to the inside of the case so that one end can rotate, and the other end of the rotating member disposed to intersect the tape wound to the maximum diameter; An elastic member mounted to the case such that the other end of the rotation member is rotated in the direction toward the tape by its elastic restoring force; A tape measure including an operation means mounted to the case so as to press the pivot member in a direction in which the other end of the pivot member is spaced apart from the tape. The tape measure according to claim 1, further comprising a friction member attached to the other end of the rotating member to contact the tape wound on the reel at an initial position of the tape to impart a friction force. The tape measure according to claim 2, wherein the friction member is formed of a friction pad fixed to the other end of the rotation member. The tape measure according to claim 2, wherein the friction member is made of a friction roller mounted to rotate at the other end of the rotation member. The method according to any one of claims 1 to 4, wherein the operation means, A push button having a button part disposed at an outer side of the case so as to be operated by a user, and a rod part formed at one side of the button part to push the pivot member through the case; Tape measure is mounted between the case and the button portion, and composed of a spring for providing an elastic force to return the push button to the initial position. The tape measure according to claim 5, further comprising: restraining means for restraining rotation of the pivot member at an initial position of the tape where the friction member is in contact with the tape. The tape measure according to claim 6, wherein the restraining means comprises a stopper provided on one side of the inner surface of the case to restrain the pivot member at an initial position of the tape. 7. The tape measure according to claim 6, wherein the restraining means comprises a stopper provided on one side of the inner surface of the case to restrain the friction member at the initial position of the tape. 7. The shaft of claim 6, wherein a shaft is formed at one end of the pivot member, and a pair of shaft holes are formed at both sides of an inner surface of the case, and the restraining means is formed on an outer surface of the shaft. A projection, a groove formed to receive the projection on an inner surface of one of the shaft holes, a first locking jaw formed on one side of the groove such that the projection interferes at an initial position of the tape, and the groove A tape measure formed on the other side of the second locking jaw formed such that the projection interferes with the projection at a release position spaced apart from the tape.

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