JP2016001010A - Rod fixing unit and extension rod unit using same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a rod fixing unit capable of suppressing the unintended movement of a rod and an extension rod unit using the same.SOLUTION: A rod fixing unit FU comprises: at least one bearing into which a moving rod Rm is inserted; a plurality of brakes 55 disposed to be aligned on a circumferential direction of the moving rod Rm and energized to press an outer circumferential surface of the moving rod Rm; and a plurality of switches 58 provided to correspond to the respective brakes 55 and moving the corresponding brakes 55 in a direction of separating from the moving rod Rm.

Description

  The present invention relates to a rod fixing unit and a telescopic rod unit using the rod fixing unit, and more particularly to a unit suitable for suppressing unintentional movement of a rod unintentionally.

  In some cases, a drip stand, a microphone stand, or the like uses a telescopic rod unit in which two rods are connected in a stretchable manner to change the height. In such a telescopic rod unit in which two rods are extendable, a small-diameter moving rod is generally inserted into a through-hole of a pipe-shaped large-diameter fixed rod, and the moving rod is longer than the fixed rod. The structure is movable along the direction. Further, such a telescopic rod unit is provided with a rod fixing unit that switches between a state in which the fixed rod and the moving rod are relatively movable and a state in which the fixed rod and the moving rod are fixed to each other.

  Patent Document 1 below describes a locking device for a slide rod. In this lock device, the lock pin is provided on the member engaged with the spring, and the lock pin is pressed against the slide rod by the elastic force of the spring. The slide rod is locked to the lock device by this pressing force. Further, a button is formed on the member, and when the button is pressed, the lock pin can be separated from the slide rod against the elastic force of the spring. Therefore, the slide rod can be slid by pressing the button.

Japanese Patent Laid-Open No. 11-276285

  In the lock device described in Patent Document 1, the locked state of the slide rod is released by operating one button. Therefore, for example, when the button is pressed unintentionally, the lock state of the slide rod is released, and the slide rod may move unintentionally. When such a locking device is used for the telescopic rod unit described above, there is a risk that the moving rod will unintentionally move and expand and contract.

  Then, an object of this invention is to provide the rod fixing unit which can suppress the movement which the rod does not intend, and an expansion-contraction rod unit using the same.

  The rod fixing unit of the present invention includes at least one bearing through which the moving rod is inserted, a plurality of brakes arranged side by side in the circumferential direction of the moving rod and biased to press the outer peripheral surface of the moving rod, And a plurality of switches that are provided corresponding to each of the plurality of brakes and that move the corresponding brakes in a direction away from the moving rod.

  The telescopic rod unit of the present invention includes the rod fixing unit, the moving rod inserted into the bearing, and a cylindrical fixed rod fixed to the rod fixing unit so that the moving rod can be inserted. It is characterized by providing.

  According to such a rod fixing unit, a plurality of brakes press the moving rod. Therefore, the moving rod can be more firmly locked to the rod fixing unit than when only one brake is provided. In addition, a switch for separating the brake from the moving rod is provided corresponding to each of the plurality of brakes. Therefore, even when a part of the switches is pressed unintentionally for some reason, at least one brake presses the moving rod unless all the switches are pressed. In such a state, as compared with a state where all the brakes press the moving rod, the balance of the pressing force applied from the brake to the moving rod is lost, and the moving rod tends to be biased in the radial direction. However, even in such a case, the brake and the bearing whose switch is not pressed presses the moving rod, and the moving rod is not completely free. Therefore, it can suppress that a moving rod moves unintentionally.

  In addition, since the unintended movement of the moving rod is suppressed in the rod fixing unit, according to the telescopic rod unit using this rod fixing unit, the moving rod is not intended for the fixed rod fixed to the rod fixing unit. It can suppress moving. Therefore, it is possible to prevent the rod from expanding and contracting unintentionally.

It is a disassembled perspective view of the rod fixing unit which concerns on embodiment of this invention. It is sectional drawing along the longitudinal direction of the rod of an expansion-contraction rod unit. It is sectional drawing perpendicular | vertical to the longitudinal direction of the rod of a rod fixing unit. FIG. 3 is an enlarged view of a region surrounded by a dotted line in FIG. 2. It is a figure which shows the mode of the expansion-contraction rod unit in the state by which a pair of switch was pushed from the same viewpoint as FIG. FIG. 6 is an enlarged view of a region surrounded by a dotted line in FIG. 5. It is a figure which shows the mode of the expansion-contraction rod unit in the state by which one switch was pushed from the same viewpoint as FIG. It is a figure which shows the gravity center position of a brake.

  Hereinafter, preferred embodiments of a rod fixing unit according to the present invention and a telescopic rod unit using the same will be described in detail with reference to the drawings.

  As shown in FIGS. 1 and 2, the telescopic rod unit EU of the present embodiment includes a moving rod Rm, a rod fixing unit FU, and a fixing rod Rf.

  The moving rod Rm and the fixed rod Rf are cylindrical rods. The inner diameter of the fixed rod Rf is made larger than the outer diameter of the moving rod Rm. Therefore, the moving rod Rm can be inserted into the through hole of the fixed rod Rf.

  1 to 3, the rod fixing unit FU includes a housing 10, a cap 21, an upper seal ring 22, an upper bearing plate 23, a lower seal ring 24, and a lower bearing plate. 25 and the brake unit 50 are provided as main components. In FIG. 1, the moving rod and the fixed rod are indicated by broken lines.

  The housing 10 includes a side wall portion 11, a bottom floor portion 12, and a rod fitting portion 13. The side wall part 11 is a cylindrical part, and a pair of notches 11C are formed. These notches 11 </ b> C are formed at positions facing each other, and have a shape extending in a direction perpendicular to the longitudinal direction of the side wall portion 11. Further, the vicinity of the opening on one side of the side wall portion 11 is formed with a small thickness, so that a cap 21 and an upper bearing plate 23 (to be described later) are fitted therein. In addition, a bottom floor portion 12 is connected to the side wall portion 11 on the other side of the side wall portion 11 so as to block a part of the opening. The bottom floor 12 is a plate-like part having a circular opening 12H formed in the center. The opening 12H has a diameter having a clearance with which the moving rod Rm can move when the moving rod Rm is inserted. A cylindrical rod fitting portion 13 is connected to the side opposite to the side wall portion 11 side of the bottom floor portion 12. The rod fitting part 13 is a part to which the fixed rod Rf is fitted. The rod fitting portion 13 has a cylindrical shape with a smaller diameter than the side wall portion 11. One end portion of the rod fitting portion 13 is connected to the bottom floor portion 12 so that the opening surrounds the opening 12H, and the other end portion is left open. Further, the inner diameter of the rod fitting portion 13 is substantially equal to the outer diameter of the fixed rod Rf, and the fixed rod Rf is press-fitted into the rod fitting portion 13 to fix the fixed rod Rf to the rod fitting portion 13. Can do. The fixed rod Rf may be fixed to the rod fitting portion 13 by a method other than press fitting. For example, the fixed rod Rf inserted into the rod fitting portion 13 may be fixed with a screw or the like. Alternatively, a thread is formed on the outer peripheral surface of the portion of the fixed rod Rf that should be positioned in the rod fitting portion 13 and the inner peripheral surface of the rod fitting portion 13, and the fixed rod Rf is screwed into the rod fitting portion 13. May be.

  The cap 21 is a plate-like member having a circular opening 21H formed at the center. The opening 21 </ b> H has the same diameter as the opening 12 </ b> H formed in the bottom floor 12 of the housing 10. The cap 21 is fitted into a portion where the thickness of the side wall portion 11 is thin so as to close the opening on one side of the side wall portion 11 of the housing 10. Further, as shown in FIG. 2, the portion surrounding the opening 21 </ b> H in the cap 21 is formed to be thin.

  The upper seal ring 22 is a circular ring and is formed of an elastic body such as rubber. The inner diameter of the upper seal ring 22 is slightly smaller than the diameter of the opening 21 </ b> H formed in the cap 21, and there is a gap between the moving rod Rm and the upper seal ring 22 when the moving rod Rm is inserted. It is said that it does not occur. The upper seal ring 22 is disposed so as to enter a portion where the plate thickness surrounding the opening 21H of the cap 21 is thin.

  The upper bearing plate 23 is a plate-like member having a circular opening 23H formed at the center. The diameter of the opening 23 </ b> H is slightly larger than the inner diameter of the upper seal ring 22 and slightly smaller than the diameter of the opening 21 </ b> H formed in the cap 21. Accordingly, the opening 23H can be inserted through the moving rod Rm with a smaller clearance than the clearance between the opening 21H and the moving rod Rm. The upper bearing plate 23 is fitted to a portion where the side wall 11 of the housing 10 is formed thin so as to overlap the cap 21. Further, the portion surrounding the opening 23H of the upper bearing plate 23 is formed to be slightly thicker. The portion where the plate thickness is thickly enters the portion where the plate thickness surrounding the opening 21 </ b> H of the cap 21 is thin with the upper bearing plate 23 overlapping the cap 21. Accordingly, the upper seal ring 22 is sandwiched between a portion where the plate thickness surrounding the opening 21H of the cap 21 is formed thin and a portion where the plate thickness of the upper bearing plate 23 is formed thick.

  The lower bearing plate 25 is a plate-like member having a circular opening 25H formed at the center. The diameter of the opening 25 </ b> H is slightly smaller than the diameter of the opening 12 </ b> H formed in the bottom floor portion 12 of the housing 10, and is the same size as the diameter of the opening 23 </ b> H of the upper bearing plate 23.

  The lower seal ring 24 has the same configuration as the upper seal ring 22. For this reason, the inner diameter of the lower seal ring 24 is slightly smaller than the diameter of the opening 25H of the lower bearing plate 25, and when the moving rod Rm is inserted, it is interposed between the moving rod Rm and the lower seal ring 24. There is no gap. The lower seal ring 24 is disposed on the lower bearing plate 25.

  When the upper seal ring 22 and the lower seal ring 24 are deformed due to an external force applied to the moving rod Rm, the moving rod Rm is pressed against the opening edge of the upper bearing plate 23 and the opening edge of the lower bearing plate 25. There is also. That is, in this embodiment, one bearing is formed by the opening edge of the upper seal ring 22 and the upper bearing plate 23, and the other bearing is formed by the opening edge of the lower seal ring 24 and the lower bearing plate 25. . When the moving rod Rm is made of metal, the upper bearing plate 23 and the lower bearing plate 25 are preferably made of resin. By using such a combination of materials, it is possible to reduce unpleasant noise even when the moving rod Rm moves in a state of being in contact with the upper bearing plate 23 and the lower bearing plate 25.

  The brake unit 50 includes a base plate 51, a pair of vertical bases 52, a pair of brakes 55, a pair of springs 57, and a pair of switches 58 as main components.

  The base plate 51 is a plate-like member having a circular opening 51H formed at the center. The diameter of the opening 51 </ b> H is the same as the diameter of the opening 12 </ b> H of the bottom floor 12 of the housing 10 and the opening 21 </ b> H of the cap 21. A portion of the base plate 51 adjacent to the opening 51H is formed with a thin plate thickness. In a state where the brake unit 50 is disposed on the lower bearing plate 25, the lower seal ring 24 enters a portion of the base plate 51 where the plate thickness is formed so that the lower bearing plate 25 and the base plate 51 Sandwiched.

  The pair of vertical bases 52 are provided on the base plate 51 so as to face each other across the opening 51H of the base plate 51. Each vertical base 52 is a plate-like part extending in a direction perpendicular to the surface direction of the base plate 51 and has the same shape. An opening (not shown) is formed on the opposite side of the vertical base 52 to the base plate 51 side. A pin 56 is inserted into this opening.

  The pair of brakes 55 are parts that press the moving rod Rm. Each brake 55 has the same shape as each other, and faces each other across the opening 51H. That is, the pair of brakes 55 are arranged side by side at positions that differ by 180 degrees in the circumferential direction of the moving rod Rm when the moving rod Rm is inserted through the opening 51H. Each brake 55 is configured by integrating a main body portion 55M, an engaging portion 55E, and a pair of force point portions 55S.

  An engaging portion 55E is connected to the main body portion 55M. A hole (not shown) through which the pin 56 is inserted is formed in the engaging portion 55E, and the engaging portion 55E is pivotally supported on the vertical base 52 by the pin 56. Accordingly, each brake 55 can rotate with respect to the center of each pin 56.

  In addition, the pair of force point portions 55 </ b> S are provided on one side and the other side of a surface that passes through the center of the pin 56 and is perpendicular to the longitudinal direction of the pin 56. Each force point portion 55S is a portion extending from the main body portion 55M to the base plate 51 side. The rod fixing unit FU of the present embodiment has a total of four force point portions 55S because the pair of force point portions 55S is provided in each of the pair of brakes 55. Each force point 55S is formed with a non-through hole. One hole in one brake 55 and one hole in the other brake 55 face each other, and the other hole in one brake 55 and the other hole in the other brake 55 face each other.

  A groove-like pad portion 55P is formed on the opposite side of the main body portion 55M from the engaging portion 55E side, and the pad portions 55P of the respective brakes 55 face each other. Each pad part 55P is a part which contacts the outer peripheral surface of the moving rod Rm. The shape perpendicular to the longitudinal direction of the groove forming each pad portion 55P is an arc shape having a diameter substantially equal to the outer peripheral surface of the moving rod Rm. The shape of the groove forming each pad portion 55P is such that the distance between the respective pad portions 55P facing each other becomes smaller when the respective brakes 55 rotate in the direction in which the opposing force point portions 55S are separated from each other. Shape. Accordingly, when the brakes 55 are rotated so that the opposing force point portions 55S approach each other, the distance between the respective pad portions 55P facing each other increases. As is clear from FIGS. 1 to 3, when the brakes 55 are rotated such that the opposing force point portions 55 </ b> S are separated from each other, the respective pad portions 55 </ b> P move to the base plate 51 side.

  The pair of springs 57 are coil springs having the same shape and the same characteristics. One spring 57 has one end inserted into a hole of one power point portion 55S of one brake 55 and the other end inserted into a hole of one force point portion 55S of the other brake 55. One end of the other spring 57 is inserted into the hole of the other force point 55S of the one brake 55, and the other end is inserted into the hole of the other force point 55S of the other brake 55. Thus, both ends of each spring 57 are inserted into the holes of the force point portions 55 </ b> S facing each other, and each spring 57 is locked across the pair of brakes 55. In this way, each spring 57 presses each force point portion 55 </ b> S while being engaged with the brake 55. Therefore, the brake 55 is urged by the elastic force of the spring 57 so that the opposing force point portions 55S rotate away from each other without any operation.

  The pair of switches 58 are portions corresponding to each of the pair of brakes 55 and are portions that move the corresponding brakes 55 in a direction away from the moving rod Rm. Each switch 58 includes an arcuate operation portion 58W and a pair of pressing portions 58P connected to both ends of the operation portion 58W. The operation part 58W has an arcuate shape that is bent to substantially the same diameter as the diameter of the side wall part 11 of the housing 10. In addition, the respective pressing portions 58P connected to the operation portion 58W have the same shape as each other and extend in parallel to each other. In addition, a convex portion that protrudes outward from the pair of pressing portions 58P is formed at the tip of the pressing portion 58P. Each switch 58 is inserted into a notch 11 </ b> C that is formed in the housing 10 so that the operation portion 58 </ b> W is positioned outside the housing 10. Specifically, the respective pressing portions 58P of the respective switches 58 are inserted into the notches 11C, and the tips of the respective pressing portions 58P come into contact with the surface opposite to the hole side in the force application portion 55S of each brake 55. ing. Further, in a state where each pressing portion 58P is inserted into the notch 11C, the convex portion formed at the tip of the pressing portion 58P is configured to be hooked on the inner peripheral surface of the side wall portion 11. That is, the switch 58 is configured so as not to come out of the state where the pressing portion 58P is inserted into the housing 10. Further, as described above, the brakes 57 are biased by the springs 57 so that the opposing force point portions 55S are rotated in directions away from each other. However, the tip of the pressing portion 58P contacts the force point portion 55S in a state where the convex portion at the tip of the pressing portion 58P is caught by the side wall portion 11. Therefore, when the switch 58 is not operated, the brake 55 does not rotate and maintains a predetermined state. In the present embodiment, the position where each pressing portion 58P presses the force point portion 55S is a position facing the hole on the surface opposite to the hole into which the spring 57 is inserted.

  Next, how the rod fixing unit FU engages the moving rod Rm at a certain position and the telescopic rod unit EU maintains a certain length will be described.

  The moving rod Rm is inserted through the rod fixing unit FU as shown in FIGS. At this time, one end of the moving rod Rm is located in the through hole of the fixed rod Rf. Further, the upper seal ring 22 and the lower seal ring 24 are in contact with the moving rod Rm without a gap. A slight clearance is formed between the upper bearing plate 23 and the lower bearing plate 25 and the moving rod Rm.

  In a state where the moving rod Rm is not inserted into the rod fixing unit FU and the switch 58 is not operated, the pressing portion 58P of the switch 58 contacts the force point portion while the elastic force of the spring 57 presses the force point portion 55S as described above. Therefore, the force point portions 55S facing each other are in a state separated from each other by a predetermined distance. This state is a state in which the opposing force point portions 55S are farthest away. At this time, the distance between the pad portions 55P facing each other is slightly smaller than the diameter of the moving rod Rm. Therefore, when the moving rod Rm is inserted through the rod fixing unit FU as described above, the respective brakes 55 are slightly rotated, and the respective pad portions 55P are moved as shown in FIG. It contacts the outer peripheral surface of Rm. In this state, the pair of pad portions 55P press the outer peripheral surface of the moving rod Rm toward each other toward the central axis of the moving rod Rm by the elastic force of the spring 57. Accordingly, the moving rod Rm is pinched by the respective brakes 55 and locked to the rod fixing unit FU. For this reason, the telescopic rod unit EU maintains a certain length.

  In this state, the telescopic rod unit EU is to be contracted. That is, the moving rod Rm tries to move into the fixed rod Rf. At this time, the brake 55 tends to rotate in the direction in which the pad portion 55P moves toward the base plate 51 due to the friction between each pad portion 55P and the moving rod Rm. However, the rotation direction of the brake 55 is a direction in which the distance between the pad portions 55P is reduced. Therefore, in order to move the moving rod Rm into the fixed rod Rf in order to shrink the telescopic rod unit EU, the brake 55 presses the moving rod Rm more firmly and locks the moving rod Rm more firmly. For example, the telescopic rod unit EU may be used while standing in a direction perpendicular to the ground with the fixed rod Rf positioned below the rod fixed unit FU. In this case, a force to move downward is applied to the moving rod Rm due to gravity. This force is a force for contracting the telescopic rod unit EU. Therefore, in a state where the telescopic rod unit EU is set up vertically, the brake 55 more firmly locks the moving rod Rm by the weight of the moving rod Rm. For this reason, it can suppress that moving rod Rm falls below by gravity.

  Next, how the moving rod Rm is moved relative to the rod fixing unit FU and the telescopic rod unit EU is expanded and contracted will be described.

  When the moving rod Rm is moved relative to the rod fixing unit FU, the opposing switch 58 is pressed as shown in FIG. Then, each pressing part 58P of the switch 58 moves each abutting force point part 55S against the elastic force of the spring 57. Specifically, when the switch 58 is pressed, the brake 55 rotates so that the spring contracts and the force point portions 55S facing each other approach each other. By this operation, the pad portion 55P is slightly separated from the outer peripheral surface of the moving rod Rm as shown in FIG. For this reason, the locking of the moving rod Rm to the rod fixing unit FU is released, and the moving rod Rm can freely move in the longitudinal direction. Therefore, the telescopic rod unit EU can be set to a desired length by moving the moving rod Rm while pressing each switch 58. When the telescopic rod unit EU reaches the desired length, the operation of the switch 58 is stopped.

  In the telescopic rod unit EU of the present embodiment, the telescopic rod unit EU may be extended in a state where the moving rod Rm is locked to the rod fixing unit FU. In this case, the brake 55 tends to rotate in the direction in which the pad portion 55P moves to the side opposite to the base plate 51 side due to friction between each pad portion 55P and the moving rod Rm. The rotation direction of the brake 55 is a direction in which the distance between the pad portions 55P increases. Accordingly, the pressing force for pressing the moving rod Rm of the brake 55 is reduced. For this reason, even if the moving rod Rm is locked to the rod fixing unit FU, the telescopic rod unit EU can be extended with a predetermined force.

  In the telescopic rod unit EU of the present embodiment, the moving rod Rm can be removed from the rod fixing unit FU by moving the moving rod Rm in the direction in which the telescopic rod unit EU extends.

  Next, the non-normal operation of the telescopic rod unit EU will be described.

  As shown in FIG. 7, when one switch 58 is not operated and the other switch 58 is operated, the brake 55 corresponding to the operated switch 58 is separated from the moving rod Rm. Then, the balance of the pressing force applied to the moving rod Rm from the pair of brakes 55 is lost. In this state, the moving rod Rm is pressed from one brake 55 and is pressed against the upper seal ring 22 and the lower seal ring 24 by this pressing force. In this case, the upper seal ring 22 and the lower seal ring 24 may be deformed, and the moving rod Rm may be pressed against the opening edge of the upper bearing plate 23 or the opening edge of the lower bearing plate 25. In the present embodiment, as described above, one bearing is formed at the opening edge of the upper seal ring 22 and the upper bearing plate 23, and the other bearing is formed at the opening edge of the lower seal ring 24 and the lower bearing plate 25. Has been. Thus, the moving rod Rm is locked to the rod fixing unit FU by the other brake 55 and the pair of bearings. Therefore, according to the rod fixing unit FU of the present embodiment, the unintended movement of the moving rod Rm can be suppressed even when the other switch 58 is unintentionally pressed.

  However, in the present embodiment, the friction coefficient between the pair of bearings and the moving rod Rm is made smaller than the friction coefficient between one brake 55 and the moving rod Rm. That is, when the pair of brakes 55 press the moving rod Rm, the magnitude of the frictional force between the moving rod Rm and the pair of brakes 55 is such that the one brake 55 and the pair of bearings in the pair of brakes move the moving rod Rm. It is assumed that the magnitude of the frictional force between the moving rod Rm, the one brake 55 and the pair of bearings in the case of pressing is larger. Therefore, by operating the other switch 58 without operating one switch 58, the force with which the rod fixing unit FU engages the moving rod Rm can be weakened. That is, according to the rod fixing unit FU of this embodiment, the force with which the rod fixing unit FU locks the moving rod Rm can be adjusted in multiple stages.

  Next, the operation when the force for urging the brake 55 does not work will be described.

  As shown in FIG. 8, the center of gravity G of the brake 55 of this embodiment is located on the moving rod Rm side with respect to the pin 56. Accordingly, when the force of the spring 57 urging the brake 55 is released in a state where the brake 55 is positioned above the base plate 51, the brake 55 has the pad portion 55P from above as shown by an arrow in FIG. Rotate to move downward. The rotation direction of the brake 55 is a direction in which the distance between the pad portions 55P facing each other is reduced. As described above, the telescopic rod unit EU may be used while standing in a direction perpendicular to the ground in a state where the fixed rod Rf is positioned below the rod fixed unit FU. This state of use is a state in which the brake 55 is positioned above the base plate 51. In such a state, it is assumed that some large impact is applied to the telescopic rod unit EU and the spring 57 is released. When such a large impact is applied, it is conceivable that the brake 55 is temporarily separated from the moving rod Rm. However, in the rod fixing unit FU of the present embodiment, the brake 55 rotates so that the pad portion 55P moves downward from above by gravity as described above. For this reason, even if the brake 55 is once separated from the moving rod Rm, the pad portion 55P of the brake 55 comes into contact with the moving rod Rm again. And the brake 55 presses the movement rod Rm using the dead weight of the movement rod Rm by the friction between the pad part 55P and the movement rod Rm. In this way, even when the spring 57 is detached while the telescopic rod unit EU is used while standing in a direction perpendicular to the ground, the movement of the moving rod Rm can be reduced.

  As described above, the rod fixing unit FU according to the present embodiment includes the pair of bearings through which the moving rod Rm is inserted, and the moving rod Rm arranged between the pair of bearings in the circumferential direction of the moving rod Rm. A pair of brakes 55 urged to press the outer peripheral surface and a pair of switches 58 provided corresponding to each of the pair of brakes 55 and moving the corresponding brakes 55 in a direction away from the moving rod Rm are provided.

  Therefore, the moving rod Rm can be locked to the rod fixing unit FU more firmly than the fixing unit provided with only one brake. In addition, since a switch 58 for separating the brake 55 from the moving rod Rm is provided corresponding to each of the pair of brakes, even if one switch 58 is unintentionally pressed for some reason, Unless both switches 58 are pressed, one brake 55 presses the moving rod Rm. In such a state, compared with a state in which the pair of brakes 55 press the moving rod Rm, the balance of the pressing force applied from the brake 55 to the moving rod Rm is lost, and the moving rod Rm is pressed in a radial direction. There is a tendency to. However, even in such a case, the brake 55 whose switch is not pressed and the pair of bearings press the moving rod Rm, and the moving rod Rm is not completely free. Therefore, it is possible to suppress the movement rod Rm from moving unintentionally.

  In the present embodiment, one bearing is formed at the opening edge of the upper seal ring 22 and the upper bearing plate 23, and the other bearing is formed at the opening edge of the lower seal ring 24 and the lower bearing plate 25. Thus, the bearing is paired, and the plurality of brakes are arranged between the bearings. However, a bearing may be comprised only from one bearing or only the other bearing among said one bearing and the other bearing. However, it is preferable to provide a pair of bearings as in this embodiment because the operation is stable when the moving rod is moved. In the present embodiment, the upper seal ring 22 and the lower seal ring 24 do not form a gap between each bearing and the moving rod Rm. However, the upper seal ring 22 and the lower seal ring 24 may not be provided, and a pair of bearings may be formed by the opening edge of the upper bearing plate 23 and the opening edge of the lower bearing plate 25. In this case, a gap is formed between each bearing and the moving rod Rm. Furthermore, even if the upper bearing plate 23 and the lower bearing plate 25 are not provided, a pair of bearings are formed by the opening edge of the opening 21H in the cap 21 and the opening edge of the opening 12H of the bottom floor 12 in the housing 10. good.

  Further, in the rod fixing unit FU of the present embodiment, the brake 55 is paired as described above, and the pair of brakes 55 and the plurality of switches 58 are disposed at positions facing each other with the moving rod Rm interposed therebetween.

  By arranging the brake 55 and the switch 58 in this way, it is easy to press each switch 58 with one hand. Therefore, it is easy to extend and contract the rod. However, since the rod fixing unit FU of the present invention has a plurality of brakes 55 and is provided with switches 58 corresponding to the respective brakes 55, for example, even if the number of brakes 55 and switches 58 is three, respectively. good. In this case, the brakes 55 are arranged side by side at positions different from each other by 120 degrees with respect to the central axis of the moving rod Rm.

  In the rod fixing unit FU of this embodiment, the magnitude of the frictional force between the moving rod Rm and the pair of brakes 55 when the pair of brakes 55 presses the moving rod Rm is the same as that of the pair of brakes 55. The frictional force between the moving rod Rm, the one brake 55 and the pair of bearings when the moving rod Rm and the bearing 55 press the moving rod Rm is larger.

  By defining the friction coefficient between the brake 55 and the moving rod Rm and the friction coefficient between the bearing and the moving rod Rm in this way, one switch 58 is operated to adjust the force with which the moving rod Rm is locked. can do. However, in the rod fixing unit FU of the present invention, the friction coefficient of the pair of bearings and the friction coefficient of the one brake 55 may be the same, and the friction coefficient of the pair of bearings is larger than the friction coefficient of the one brake 55. It may be large.

  In the rod fixing unit FU of the present embodiment, the spring 57 is locked over the pair of brakes 55 and urges each brake so that each brake 55 presses the outer peripheral surface of the moving rod Rm. To do.

  In this way, by urging the brakes 55 with the common spring 57, the urging forces related to the brakes 55 can be made uniform. Therefore, it is possible to balance the force with which each brake 55 presses the moving rod Rm. However, the rod fixing unit FU of the present invention may be configured such that a different spring is locked for each brake 55.

  Further, in the rod fixing unit FU of the present embodiment, the brake 55 is pivotally supported, and when the urging force for urging the brake 55 is released in a state where the moving rod Rm is vertically set, the force is reduced by gravity. As the brake 55 rotates, the pad portion 55P that contacts the outer peripheral surface of the moving rod Rm moves downward from above, and the brake 55 presses the moving rod Rm.

  The moving rod Rm is used in a state where the moving rod Rm is set up vertically, and even when the urging force to the brake 55 is released by the release of the spring or the like by rotating the brake 55 in this way, the moving rod Rm Unintentional movement can be reduced. However, it is not essential for the rod fixing unit FU of the present invention to be configured in this way. For example, the moving rod Rm may be used in a state where the moving rod Rm is vertically set, and the brake 55 may not press the moving rod Rm when the urging force to the brake 55 is released due to the spring being removed.

  The telescopic rod unit EU of the present embodiment includes a rod fixing unit FU, a moving rod Rm inserted into the bearing, and a cylindrical fixing rod fixed to the rod fixing unit FU so that the moving rod Rm can be inserted. Rf.

  Since the unintended movement of the moving rod Rm is suppressed in the rod fixing unit FU as described above, according to the telescopic rod unit EU using the rod fixing unit FU, with respect to the fixed rod Rf fixed to the rod fixing unit FU. Thus, the movement rod Rm can be prevented from moving unintentionally. Therefore, it is possible to prevent the rod from expanding and contracting unintentionally.

  Further, as described above, the fixed rod Rf is fixed to the rod fitting portion 13 of the rod fixing unit FU by press-fitting, screwing, or the like. In this case, the fixing rod Rf can be removed from the rod fixing unit FU.

  Therefore, when the telescopic rod unit EU is accommodated, it can be made more compact. The fixed rod unit Rf may be fixed to the rod fitting portion 13 so that it cannot be detached from the rod fixing unit FU.

  Further, the moving rod Rm can be extracted from the rod fixing unit FU. Therefore, the moving rod Rm having an arbitrary length can be used in accordance with the usage application of the telescopic rod unit EU. In addition, it is good also as a structure where a moving rod Rm is provided with a retaining mechanism so that the moving rod Rm cannot be removed from the rod fixing unit FU.

  As mentioned above, although this invention was demonstrated to the example for embodiment, this invention is not limited to these.

  For example, in the above embodiment, the moving rod Rm and the fixed rod Rf are cylindrical. However, the moving rod Rm and the fixed rod Rf may have other shapes. For example, the moving rod Rm and the fixed rod Rf may be formed of a hexagonal tube. Further, the moving rod Rm may be a columnar rod.

  As described above, according to the present invention, a rod fixing unit that can suppress unintentional movement of the rod and a telescopic rod unit using the rod fixing unit are provided and used in the fields of an infusion stand, a microphone stand, and the like. be able to.

EU ... telescopic rod unit FU ... rod fixing unit Rf ... fixed rod Rm ... moving rod 10 ... casing 21 ... cap 22 ... upper seal ring 23 ... upper bearing Plate 24 ... Lower seal ring 25 ... Lower bearing plate 50 ... Brake unit 51 ... Base plate 52 ... Vertical base 55 ... Brake 58 ... Switch

Claims (9)

At least one bearing through which the moving rod is inserted;
A plurality of brakes arranged side by side in the circumferential direction of the moving rod and biased to press the outer peripheral surface of the moving rod;
A plurality of switches provided corresponding to each of the plurality of brakes and moving the corresponding brakes in a direction away from the moving rod;
A rod fixing unit comprising: The bearing is a pair,
The rod fixing unit according to claim 1, wherein the plurality of brakes are disposed between the bearings. The plurality of brakes are a pair of brakes,
3. The rod fixing unit according to claim 1, wherein the pair of brakes and the plurality of switches are arranged at positions facing each other across the moving rod. When the pair of brakes presses the moving rod, the magnitude of the frictional force between the moving rod and the pair of brakes is determined when one brake and the bearing in the pair of brakes press the moving rod. 4. The rod fixing unit according to claim 3, wherein a frictional force between the movable rod and the one brake and the bearing is larger. 5. The spring according to claim 3, further comprising a spring that is locked across the pair of brakes and biases each of the brakes such that each of the brakes presses an outer peripheral surface of the moving rod. Rod fixing unit as described. Each of the brakes is pivotally supported,
When the urging force for urging the brake is released in a state where the moving rod is set up vertically, the portion of the brake that contacts the outer peripheral surface of the moving rod due to the rotation of the brake due to gravity is lowered from above. The rod fixing unit according to claim 1, wherein the brake presses the moving rod. The rod fixing unit according to any one of claims 1 to 6,
The moving rod inserted into the bearing;
A cylindrical fixed rod fixed to the rod fixing unit so that the moving rod can be inserted;
A telescopic rod unit comprising: The telescopic rod unit according to claim 7, wherein the fixing rod is removable from the rod fixing unit. The telescopic rod unit according to claim 8, wherein the moving rod can be removed from the rod fixing unit.

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