JP2013131812A - Telescopic pole - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a telescopic pole capable of easily enhancing rigidity when being extended.SOLUTION: A telescopic pole comprises an outer casing, a first fitting part and a second fitting part. The outer casing has a first cylinder part and a second cylinder part that is inserted into an inner part of the first cylinder part, and can be extended by moving the second cylinder part in an axial direction of the first cylinder part. The first fitting part is provided at an inner peripheral part of the first cylinder part. The second fitting part is provided at an outer peripheral part of the second cylinder part, fits the first fitting part when the outer casing is extended and thereby prevents the second cylinder part from swaying with respect to the first cylinder part.

Description

  Embodiments described herein relate generally to a telescopic pole.

  For example, a truck equipped with an antenna includes a pole that supports the antenna. The pole is configured to be extendable to adjust the height of the antenna. The pole is generally expanded and contracted by a hydraulic or electric mechanism.

JP-A-8-14210

  If the rigidity of the pole is low, the pole supporting the antenna may wobble. In order to suppress this wobble, there is a method of locking each part of the multistage pole. However, it takes time and effort because an operator manually locks each part.

  An object of the present invention is to provide a telescopic pole that can easily increase the rigidity at the time of extension.

  The telescopic pole according to one embodiment includes an outer cylinder, a first fitting portion, and a second fitting portion. The outer cylinder has a first cylinder part and a second cylinder part inserted into the first cylinder part, and the second cylinder part is an axial direction of the first cylinder part. It can be expanded and contracted by moving to. The first fitting portion is provided on an inner peripheral portion of the first tube portion. The second fitting portion is provided on an outer peripheral portion of the second cylindrical portion, and the outer cylinder is extended to be fitted into the first fitting portion, and the second cylindrical portion is Oscillating with respect to the first tube portion is restricted.

1 is a side view schematically showing a vehicle according to a first embodiment. Sectional drawing which shows the antenna unit of 1st Embodiment. The perspective view which cuts and shows the 1st cylinder part of 1st Embodiment by a quarter. The perspective view which shows the 2nd cylinder part of 1st Embodiment by notching a quarter. The perspective view which cuts and shows the 1st inner cylinder of 1st Embodiment. The perspective view which shows three 2nd inner cylinders of 1st Embodiment by notching a quarter. Sectional drawing which shows the expansion-contraction pole to which the 2nd cylinder part of 1st Embodiment moved. Sectional drawing which shows the expansion-contraction pole to which one 1st cylinder part of 1st Embodiment moved. Sectional drawing which shows the expansion-contraction pole to which the other 1st cylinder part of 1st Embodiment moved. Sectional drawing which shows the expansion-contraction pole which concerns on 2nd Embodiment. Sectional drawing which shows the expansion-contraction pole which concerns on 3rd Embodiment. Sectional drawing which shows the expansion-contraction pole which concerns on 4th Embodiment.

  A first embodiment will be described below with reference to FIGS. 1 to 9. Note that in the embodiments disclosed below, the same reference numerals are assigned to components having the same functions. Further, the description of the components may be partially or entirely omitted.

  FIG. 1 is a side view schematically showing the vehicle 1. As shown in FIG. 1, the vehicle 1 is a truck. The vehicle 1 includes a shelter 11, a plurality of jacks 12, and an antenna unit 13.

  The shelter 11 is disposed behind the vehicle 1 and is formed in a rectangular box shape. The shelter 11 houses various electronic devices, a generator, and other devices. The jacks 12 are respectively disposed at the front end and the rear end of the vehicle 1. The jack 12 extends and contracts by, for example, hydraulic pressure, and lifts the vehicle 1 stably.

  The antenna unit 13 is disposed on the upper surface of the shelter 11. The antenna unit 13 includes an antenna 16, an extendable pole 17, and a support base 18. The antenna 16 is an example of a mounted object. The telescopic pole 17 stands up from the support base 18 so as to be telescopic, and supports the antenna 16. The support base 18 is fixed to the upper surface of the shelter 11.

  FIG. 2 is a cross-sectional view showing the antenna unit 13. In FIG. 2, the antenna 16 is indicated by a two-dot chain line. As shown in FIG. 2, the telescopic pole 17 includes an outer cylinder 21, a rotation drive unit 22, and a cable 23.

  The outer cylinder 21 has three first cylinder parts 25, 26, 27 and a second cylinder part 28. The first cylinder portion 25 is disposed on the outermost side of the outer cylinder 21 and is fixed to the support base 18. The first cylinder part 26 is inserted into the first cylinder part 25. The first cylinder part 27 is inserted into the first cylinder part 26. The second cylinder portion 28 is inserted into the first cylinder portion 27.

  The first tube portion 25 includes a first fitting portion 31, a female screw portion 32, a lock portion 33, and a dust seal 34. The first fitting portion 31, the female screw portion 32, the lock portion 33, and the dust seal 34 are provided on the inner peripheral portion of the first cylindrical portion 25, respectively.

  The first fitting portion 31 protrudes from the inner peripheral surface of the first tube portion 25 and is formed integrally with the first tube portion 25. The first fitting portion 31 is formed in an annular shape having a tapered inner peripheral surface that tapers toward the tip of the first tube portion 25. In the present specification, the term “tip” refers to the end (upward) facing the antenna 16.

  The female screw portion 32 is closer to the proximal end of the first cylindrical portion 25 than the first fitting portion 31. In this specification, the term “proximal end” refers to the end (downward) facing the shelter 11. The female screw portion 32 is provided over a certain length in the axial direction of the first tube portion 25.

  The lock portion 33 is disposed at the proximal end of the first tube portion 25. The lock portion 33 is formed in an annular shape and is fitted inside the first tube portion 25. The lock part 33 is fixed to the first cylinder part 25.

  The dust seal 34 is disposed at the tip of the first cylinder portion 25. The dust seal 34 is formed in an annular shape by synthetic rubber, for example. The dust seal 34 is fitted inside the first cylinder part 25 and closes the gap between the first cylinder part 25 and the inner first cylinder part 26.

  FIG. 3 is a perspective view showing the first cylindrical portion 26 with a quarter cut. As shown in FIG. 3, the first tube portion 26 has a first fitting portion 31, a female screw portion 32, a lock portion 33, and a dust seal 34, similarly to the first tube portion 25. doing. The first fitting portion 31, the female screw portion 32, the lock portion 33, and the dust seal 34 are respectively provided on the inner peripheral portion of the first cylindrical portion 26.

  The first tube portion 26 further includes a second fitting portion 36 and a male screw portion 37. The second fitting portion 36 and the male screw portion 37 are provided on the outer peripheral portion of the first cylindrical portion 26, respectively.

  The second fitting portion 36 protrudes from the outer peripheral surface of the first tube portion 26 and is formed integrally with the first tube portion 26. The second fitting portion 36 is formed in an annular shape having a tapered outer peripheral surface that tapers toward the tip of the first tube portion 26. The second fitting portion 36 is provided corresponding to the first fitting portion 31 of the outer first tube portion 25.

  The male screw portion 37 is provided at the proximal end of the first tube portion 26. The male screw portion 37 is fitted to the female screw portion 32 of the first outer cylinder portion 25. For this reason, the 1st cylinder part 26 is movable to the axial direction of the 1st cylinder part 25 by rotating.

  As shown in FIG. 2, the first cylindrical portion 27 includes a first fitting portion 31, a female screw portion 32, a lock portion 33, a dust seal 34, Two fitting portions 36 and a male screw portion 37 are provided. The first fitting portion 31, the female screw portion 32, the lock portion 33, and the dust seal 34 are provided on the inner peripheral portion of the first cylindrical portion 27, respectively. The second fitting portion 36 and the male screw portion 37 are provided on the outer peripheral portion of the first cylindrical portion 27, respectively.

  FIG. 4 is a perspective view showing the second cylindrical portion 28 with a quarter cut. As shown in FIG. 4, the second cylindrical portion 28 has a second fitting portion 36 and a male screw portion 37, similarly to the first cylindrical portions 26 and 27. The second fitting portion 36 and the male screw portion 37 are provided on the outer peripheral portion of the second cylindrical portion 28, respectively.

  The male screw portion 37 of the second cylindrical portion 28 is fitted to the female screw portion 32 of the inner first cylindrical portion 27. For this reason, the 2nd cylinder part 28 can move to the axial direction of the 1st cylinder part 27 by rotating.

  The second cylinder portion 28 further includes a plurality of engaging portions 41 and a receiving portion 42. The engaging portions 41 protrude from the inner peripheral surface of the second cylindrical portion 28, respectively. The engaging portion 41 is formed integrally with the second cylindrical portion 28, respectively.

  The receiving portion 42 is in contact with the engaging portion 41 from the base end side of the second cylindrical portion 28. The receiving portion 42 is formed in an annular shape and is fitted inside the second cylindrical portion 28. The receiving part 42 is fixed to the second cylinder part 28.

  As shown in FIG. 2, the rotation driving unit 22 includes a first inner cylinder 45, three second inner cylinders 46, 47, 48, and a driving unit 49. The second inner cylinder 48 is inserted into the second cylinder portion 28. The second inner cylinder 47 is inserted into the second inner cylinder 48. The second inner cylinder 46 is inserted into the second inner cylinder 47. The first inner cylinder 45 is inserted into the second inner cylinder 46.

  FIG. 5 is a perspective view showing the first inner cylinder 45 with a quarter cut. As shown in FIG. 5, the first inner cylinder 45 is a hollow spline shaft. The first inner cylinder 45 has a plurality of first protrusions 51.

  The first protrusion 51 is provided at the tip of the first inner cylinder 45. The first projecting portions 51 are formed integrally with the first inner cylinder 45 and project radially from the outer peripheral surface of the first inner cylinder 45.

  FIG. 6 is a perspective view showing the three second inner cylinders 46, 47, and 48 by cutting each quarter. As shown in FIG. 6, the second inner cylinders 46, 47, 48 are hollow spline shafts provided with spline grooves on the inner peripheral surface.

  The innermost second inner cylinder 46 is provided with a plurality of first groove portions 53 and a plurality of inner cylinder protrusions 54. The first groove portion 53 is provided in the inner peripheral portion of the second inner cylinder 46. The inner cylinder projecting portion 54 is provided on the outer peripheral portion of the second inner cylinder 46.

  The first groove 53 is recessed from the inner peripheral surface of the second inner cylinder 46. The first groove portions 53 extend in the longitudinal direction of the first inner cylinder 46. The first groove 53 is closed at the proximal end of the second inner cylinder 46.

  The first groove 53 and the first protrusion 51 of the first inner cylinder 45 are fitted so that the first protrusion 51 can slide in the longitudinal direction of the first inner cylinder 45. . That is, the first inner cylinder 45 and the second inner cylinder 46 are spline-fitted. For this reason, the first inner cylinder 45 is movable in the axial direction of the second inner cylinder 46.

  The inner cylinder protruding portion 54 is provided at the tip of the second inner cylinder 46. The inner cylinder protruding portion 45 is formed integrally with the second inner cylinder 46 and protrudes radially from the outer peripheral surface of the second inner cylinder 46.

  Similar to the second inner cylinder 46, a plurality of inner cylinder protrusions 54 are provided on the second inner cylinder 47. The second inner cylinder 47 is further provided with a plurality of inner cylinder grooves 55. The inner cylinder groove 55 is provided in the inner peripheral portion of the second inner cylinder 47.

  The inner cylinder groove 55 is recessed from the inner peripheral surface of the second inner cylinder 47. The inner cylinder groove 55 extends in the longitudinal direction of the second inner cylinder 47. The inner cylinder groove 55 is closed at the base end of the second inner cylinder 47.

  The inner cylinder groove 55 and the inner cylinder protrusion 54 of the second inner cylinder 46 are fitted so that the inner cylinder protrusion 54 can slide in the longitudinal direction of the second inner cylinder 46. That is, the two second inner cylinders 46 and 47 are spline-fitted. For this reason, the second inner cylinder 46 is movable in the axial direction of the second inner cylinder 47.

  Similar to the second inner cylinder 47, a plurality of inner cylinder grooves 55 are provided in the second inner cylinder 48. The second inner cylinder 48 is further provided with a plurality of second protrusions 56. The second projecting portion 56 is provided on the outer peripheral portion of the second inner cylinder 48.

  The second protrusion 56 is provided at the tip of the second inner cylinder 48. The second projecting portions 56 are formed integrally with the second inner cylinder 48 and project radially from the outer peripheral surface of the second inner cylinder 48.

  As shown in FIG. 2, the 2nd protrusion part 56 and the some 2nd groove part 58 which the engaging part 41 provided in the 2nd cylinder part 28 forms are fitted. That is, the second cylinder portion 28 and the second inner cylinder 48 are spline-fitted. The second projecting portions 56 are respectively supported by the receiving portion 42.

  The drive unit 49 is accommodated in the support base 18. The drive unit 49 is connected to the first inner cylinder 45. The drive unit 49 is, for example, a motor, and rotates the first inner cylinder 45 in an arbitrary direction.

  The cable 23 is disposed through the inside of the hollow first inner cylinder 45. One end of the cable 23 is connected to, for example, an electronic device accommodated in the shelter 11. The other end of the cable 23 is connected to the antenna 16.

The telescopic pole 17 configured as described above expands and contracts as follows.
As shown in FIG. 2, the telescopic pole 17 is usually shortened. When extending the telescopic pole 17, the first inner cylinder 45 is rotated by the drive unit 49. When the first inner cylinder 45 is rotated, rotational torque is transmitted from the first inner cylinder 45 to the second inner cylinders 46, 47 and 48 and the second cylinder portion 28.

  FIG. 7 is a cross-sectional view showing the telescopic pole 17 to which the second cylindrical portion 28 has moved. As shown in FIG. 6, when the rotational torque is transmitted to the second cylindrical portion 28, the second cylindrical portion 28 rotates. At the same time, the second cylindrical portion 28 moves in the axial direction (upward) of the first cylindrical portion 27 by the female screw portion 32 and the male screw portion 37, and the outer cylinder 21 extends.

  As the outer cylinder 21 extends, the second protrusion 56 of the second inner cylinder 48 is pulled up by the receiving part 42 of the second cylinder part 28. As a result, the second inner cylinder 48 is lifted by the second cylinder portion 28, and the second inner cylinder 48 moves in the axial direction (upward) of the second inner cylinder 47.

  When the outer cylinder 21 extends, the second fitting part 36 of the second cylinder part 28 is fitted into the first fitting part 31 of the first cylinder part 27. The outer peripheral surface of the second fitting portion 36 is in surface contact with the inner peripheral surface of the first fitting portion 31. By fitting the first fitting portion 31 and the second fitting portion 36, the second tube portion 28 is fixed to the first tube portion 27 with high rigidity, and the second tube portion 28 is restricted from swinging with respect to the first cylindrical portion 27. Further, the second cylinder part 28 is restricted from moving further with respect to the first cylinder part 27.

  FIG. 8 is a cross-sectional view showing the telescopic pole 17 to which the first cylindrical portion 27 has moved. When the movement of the second tube portion 28 is restricted, the rotational torque is transmitted to the first tube portion 27 via the second tube portion 28. Thereby, the 1st cylinder part 27 moves to the axial direction (upward) of the 1st cylinder part 26 by rotating, and the outer cylinder 21 further expand | extends.

  As the outer cylinder 21 extends, the inner cylinder protruding portion 54 of the second inner cylinder 47 is pulled up by the proximal end of the second inner cylinder 48. The proximal end of the second inner cylinder 48 closes the inner cylinder groove 55. Accordingly, the second inner cylinder 48 is lifted by the second inner cylinder 48, and the second inner cylinder 47 moves in the axial direction (upward) of the second inner cylinder 46.

  When the outer cylinder 21 extends, the second fitting part 36 of the first cylinder part 27 is fitted to the first fitting part 31 of the first cylinder part 26. As a result, the first cylinder part 27 is fixed to the first cylinder part 26 with high rigidity, and the first cylinder part 27 is restricted from swinging with respect to the first cylinder part 26. Furthermore, the first cylinder part 27 is restricted from moving further with respect to the first cylinder part 26.

  FIG. 9 is a cross-sectional view showing the telescopic pole 17 to which the first cylindrical portion 26 has moved. When the movement of the first tube portion 27 is restricted, the rotational torque is transmitted to the first tube portion 26 via the first tube portion 27. Thereby, the 1st cylinder part 26 moves to the axial direction (upward) of the 1st cylinder part 25 by rotating, and the outer cylinder 21 further expand | extends.

  As the outer cylinder 21 extends, the inner cylinder protruding portion 54 of the second inner cylinder 46 is pulled up by the proximal end of the second inner cylinder 47. The proximal end of the second inner cylinder 47 closes the inner cylinder groove 55. Accordingly, the second inner cylinder 47 is lifted by the second inner cylinder 47, and the second inner cylinder 46 moves in the axial direction (upward) of the first inner cylinder 45.

  When the outer cylinder 21 extends, the second fitting part 36 of the first cylinder part 26 is fitted to the first fitting part 31 of the first cylinder part 25. Thereby, the 1st cylinder part 26 is fixed to the 1st cylinder part 25 with high rigidity, and it is controlled that the 1st cylinder part 26 rock | fluctuates with respect to the 1st cylinder part 25. FIG. Further, the further movement of the first cylindrical portion 26 relative to the first cylindrical portion 25 is restricted, and the extension of the telescopic pole 17 is completed.

  When the telescopic pole 17 is shortened, the first inner cylinder 45 is rotated by the drive unit 49 in the opposite direction to the case where the telescopic pole 17 is extended. When the first inner cylinder 45 is rotated in the reverse direction, rotational torque is transmitted from the first inner cylinder 45 to the second inner cylinders 46, 47, 48 and the second cylinder portion 28.

  When the rotational torque is transmitted to the second cylindrical portion 28, the second cylindrical portion 28 rotates in the reverse direction, and a high load is generated by the female screw portion 32 and the male screw portion 37. Thereby, the fitting between the second fitting part 36 of the second cylinder part 28 and the first fitting part 31 of the first cylinder part 27 is released. The second cylinder part 28 moves in the axial direction (downward) of the first cylinder part 27, and the outer cylinder 21 is shortened.

  When the outer cylinder 21 is shortened, the proximal end of the second cylinder part 28 comes into contact with the lock part 33 of the first cylinder part 27. The lock part 33 restricts the second cylinder part 28 from rotating further backward with respect to the first cylinder part 27.

  When the movement of the second tube portion 28 is restricted, the rotational torque is transmitted to the first tube portion 27 via the second tube portion 28. Thereby, the 1st cylinder part 27 moves to the axial direction (downward) of the 1st cylinder part 26 by reversely rotating, and the outer cylinder 21 further shortens.

  When the outer cylinder 21 is shortened, the base end of the first cylinder part 27 comes into contact with the lock part 33 of the first cylinder part 26. The lock portion 33 restricts the first tube portion 27 from rotating further backward with respect to the first tube portion 26.

  When the movement of the first tube portion 27 is restricted, the rotational torque is transmitted to the first tube portion 26 via the first tube portion 27. Thereby, the 1st cylinder part 26 moves to the axial direction (downward) of the 1st cylinder part 25 by reversely rotating, and the outer cylinder 21 further shortens.

  When the outer cylinder 21 is shortened, the base end of the first cylinder part 26 comes into contact with the lock part 33 of the first cylinder part 25. The lock portion 33 restricts the first tube portion 26 from rotating further backward with respect to the first tube portion 25. Thereby, shortening of the telescopic pole 17 is completed as shown in FIG.

  The order in which the second cylindrical portions 26, 27, and 28 are moved is not limited to the above order. For example, the second cylinder part 27 may start moving before the second cylinder part 28. In addition, in most cases, it is the second cylindrical portion 28 having the smallest diameter that starts moving first.

  According to the telescopic pole 17 having the above-described configuration, the outer tube 21 extends, whereby the second fitting portion 36 is fitted to the first fitting portion 31, and the first and second tube portions 25 to 28 are fitted. Is restricted from swinging. That is, as the outer cylinder 21 extends, the first and second cylinder portions 25 to 28 are locked. Thereby, the rigidity of the expansion / contraction pole 17 at the time of expansion | extension becomes high, and it is suppressed that the expansion / contraction pole 17 wobbles. Further, since the extension work and the locking work of the telescopic pole 17 are performed simultaneously, the locking becomes easy and the workability is improved.

  The first fitting portion 31 is formed in an annular shape having a tapered inner peripheral surface. The second fitting portion 36 is formed in an annular shape having a tapered outer peripheral surface. Thereby, the lock load is improved and the swinging of the first and second cylindrical portions 25 to 28 can be stably regulated. In addition, the first fitting portion 31 and the second fitting portion 36 can be easily fitted and released.

  As the outer cylinder 21 is shortened, the base ends of the first and second cylinder parts 26, 27, and 28 come into contact with the lock part 33, and the first and second cylinder parts 26, 27, and 28 rotate in reverse. Is regulated. Thereby, the telescopic pole 17 can be shortened easily.

  By rotating the first inner cylinder 45 by the drive unit 49, the telescopic pole 17 is extended. Moreover, the telescopic pole 17 is shortened by reversely rotating the first inner cylinder 45 by the drive unit 49. In this way, the telescopic pole 17 can be easily expanded and contracted simply by operating the drive unit 49. Furthermore, the first and second cylindrical portions 25 to 28 can be locked by operating the driving portion 49, and the work becomes easy.

  Next, a second embodiment will be described with reference to FIG. FIG. 10 is a cross-sectional view showing the telescopic pole 17 according to the second embodiment. As shown in FIG. 10, the first tube portions 25, 26, and 27 of the second embodiment have the first fitting portion 61 instead of the first fitting portion 31 of the first embodiment. Each has.

  The first fitting portion 61 has a tapered roller bearing 62 and a contact portion 63, respectively. The tapered roller bearing 62 is an example of a thrust bearing. Tapered roller bearings 62 are attached to the inner peripheral portions of the first cylindrical portions 25, 26, and 27, respectively.

  The contact portion 63 is formed in an annular shape having a tapered inner peripheral surface that tapers toward the tip of each of the first cylindrical portions 25, 26, and 27. The contact portions 63 are respectively fitted inside the tapered roller bearings 62.

  When the telescopic pole 17 is extended, the second fitting portions 36 of the first and second cylindrical portions 26, 27, and 28 are fitted into the first fitting portions 61, respectively. At this time, the contact part 63 fitted inside the taper roller bearing 62 can be rotated in accordance with the second fitting part 36 that rotates at the time of contact.

  According to the telescopic pole 17 configured as described above, it is possible to reduce friction when the first fitting portion 61 and the second fitting portion 36 are fitted. The thrust bearing is not limited to the tapered roller bearing 62, and may be a composite bearing having rigidity in the thrust direction, such as an angular bearing or a cross roller bearing.

  Next, a third embodiment will be described with reference to FIG. FIG. 11 is a cross-sectional view showing the telescopic pole 17 according to the third embodiment. As shown in FIG. 11, the first cylindrical portions 25, 26, and 27 of the third embodiment each have a lock portion 65 instead of the lock portion 33 of the first embodiment.

  The lock portion 65 includes a tapered roller bearing 66 and a contact portion 67. The tapered roller bearing 66 is an example of a thrust bearing. The taper roller bearing 66 is attached to the inner peripheral portion of the first cylindrical portions 25, 26, and 27, respectively.

  The contact portion 67 is formed in an annular shape having a tapered inner peripheral surface that tapers toward the base end of each of the first cylindrical portions 25, 26, 27. The contact portions 67 are fitted inside the tapered roller bearings 66, respectively.

  Tapered surfaces 68 are respectively provided at the base end portions of the first and second cylindrical portions 26, 27 and 28. The tapered surface 68 is an outer peripheral surface of each of the first and second cylindrical portions 26, 27, 28 that taper toward the base end.

  When the telescopic pole 17 is shortened, the tapered surfaces 68 of the first and second cylindrical portions 26, 27, and 28 are fitted into the lock portions 65, respectively. At this time, the abutting portion 67 fitted inside the tapered roller bearing 66 can rotate according to the tapered surface 68 that rotates upon contact.

  According to the telescopic pole 17 configured as described above, the contact portion 67 of the lock portion 65 is formed in an annular shape having a tapered inner peripheral surface. A tapered surface 68 is formed at the base end portions of the first and second cylindrical portions 26, 27, 28. Thereby, the lock load is improved, and the swinging of the first and second cylindrical portions 25 to 28 can be stably regulated even when shortening.

  Further, the taper roller bearing 66 can reduce friction when the base ends of the first and second cylindrical portions 26, 27, 28 abut against the lock portion 65. The thrust bearing is not limited to the tapered roller bearing 66, and may be a composite bearing having rigidity in the thrust direction, such as an angular bearing or a cross roller bearing.

  Next, a fourth embodiment will be described with reference to FIG. FIG. 12 is a cross-sectional view showing the telescopic pole 17 according to the fourth embodiment. As shown in FIG. 12, the first and second tube portions 26, 27, 28 of the fourth embodiment have two male screw portions 37, respectively. The two male screw portions 37 are arranged side by side in the longitudinal direction and are fitted to the female screw portion 32, respectively.

  According to the telescopic pole 17 having the above configuration, the two male screw portions 37 arranged side by side in the longitudinal direction are fitted to the female screw portion 32, respectively. Thereby, the rigidity of the telescopic pole 17 can be improved. Furthermore, an increase in weight due to an increase in the number of male screw portions 32 can be suppressed.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  For example, the length and the number of the cylindrical portions are determined depending on the application. Further, for example, a key may be employed instead of the first projecting portion 51. Furthermore, the movement of the second cylindrical portions 26, 27, 28 in the axial direction is not limited to the rotation drive unit 22, the female threaded portion 32, and the male threaded portion 37, but other movements such as a hydraulic jack, for example. It may be performed by a device. Further, the first and second fitting portions are not limited to the annular portion having a tapered surface, and may be, for example, an annular portion having a rectangular cross section.

  DESCRIPTION OF SYMBOLS 16 ... Antenna, 17 ... Telescopic pole, 21 ... Outer cylinder, 22 ... Rotation drive part, 23 ... Cable, 25, 26, 27 ... 1st cylinder part, 28 ... 2nd cylinder part, 31, 61 ... 1st Fitting part, 32 ... female screw part, 33, 65 ... lock part, 36 ... second fitting part, 37 ... male screw part, 45 ... first inner cylinder, 46, 47, 48 ... second Inner cylinder, 49... Driving portion, 51... First protrusion, 53... First groove, 56... Second protrusion, 58.

Claims (10)

It has a 1st cylinder part and the 2nd cylinder part inserted in the inside of the 1st cylinder part, and the 2nd cylinder part moves to the axial direction of the 1st cylinder part. A telescopic outer cylinder,
A first fitting portion provided on an inner peripheral portion of the first tube portion;
The outer cylinder is provided at an outer peripheral portion of the second cylinder part, and the outer cylinder extends to fit into the first fitting part, and the second cylinder part swings with respect to the first cylinder part. A second fitting portion for restricting movement;
A telescopic pole characterized by comprising: The first fitting portion is formed in an annular shape having a tapered inner peripheral surface,
2. The telescopic pole according to claim 1, wherein the second fitting portion is formed in an annular shape having a tapered outer peripheral surface that contacts the inner peripheral surface of the first fitting portion. An internal thread portion provided on an inner peripheral portion of the first cylindrical portion;
A male screw portion provided on the outer peripheral portion of the second cylindrical portion and fitted to the female screw portion;
A rotation drive unit that moves the second cylinder part in the axial direction of the first cylinder part by rotating the second cylinder part;
The telescopic pole according to claim 2, further comprising: The rotational drive unit is
A first inner cylinder;
A second inner cylinder that is inserted into the first inner cylinder so as to be movable in the axial direction, and that transmits the rotation of the first inner cylinder to the second cylinder portion;
A drive unit for rotating the first inner cylinder;
The telescopic pole according to claim 3, further comprising:   The first cylinder part is in contact with an end part of the second cylinder part by shortening the outer cylinder, and restricts the second cylinder part from being rotated in a direction to shorten the outer cylinder. The telescopic pole according to claim 4, further comprising a lock portion. The first protrusion provided on the outer periphery of the first inner cylinder and the first groove provided on the inner periphery of the second inner cylinder are configured such that the first protrusion is the first protrusion. 1 is fitted so as to be slidable in the longitudinal direction of the inner cylinder,
The second projecting portion provided on the outer peripheral portion of the second inner cylinder and the second groove portion provided on the inner peripheral portion of the second cylindrical portion are fitted together. 5. The telescopic pole according to 5.   The telescopic pole according to claim 6, wherein at least one of the first fitting portion and the second fitting portion has a thrust bearing. The lock portion is formed in an annular shape having a tapered inner peripheral surface,
The telescopic pole according to claim 6, wherein an end portion of the second cylindrical portion is formed in an annular shape having a tapered outer peripheral surface that abuts on an inner peripheral surface of the lock portion.   The telescopic pole according to claim 6 or 8, wherein the lock portion includes a thrust bearing.   The telescopic pole according to claim 6, further comprising a cable that passes through the inside of the first inner cylinder and is connected to a placement object supported by the second cylinder portion.

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