NL9200802A - Extendable and retractable baton. - Google Patents

Description

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Extendable and retractable baton

The invention relates to a construction for extending and retracting a tubular baton with a telescopic construction and, more particularly, it relates to a construction with which the baton can be extended and retracted particularly evenly, without rattling or skipping , where this baton has greater durability.

A construction is known in which a number of cylindrical parts of different diameter are telescopically combined with one another, an oblique outer surface at the rear end of an inner cylindrical element engaging an inclined inner surface at the top end of a cylindrical element just such that it cannot shift relative to each other. This concerns a key holder with a telescopic construction which is not a baton itself, but which can be used for it (US patent 4 752 072). In this known construction, both the outer surface and the inner surface at the end of the outer cylindrical element are designed as oblique surfaces that tap to the top, while both the outer surface and the inner surface at the rear end of the inner cylindrical element are designed as up to the back end tapered sloping surfaces. Therefore, this construction has the following problems.

(1) The top end of the inner bevel surface of the outer cylindrical member is in sliding contact with the outer cylindrical surface of the inner cylindrical member over substantially an annular contact line, and the rear end of the outer bevel surface of the inner cylindrical member is also in a sliding contact with the inner cylindrical surface of the outer cylindrical element / over substantially an annular contact line and in this state they are guided during extension and retraction. The upper end of the guide of the outer cylindrical element and the rear end of the guide of the inner cylindrical element can thereby be abraded and, as a result, the play in the guide portion increases, causing rattling or jerking.

(2) The stiffness of the baton in the extended state is insufficient and is believed to be caused by the rattling described above. In particular, sometimes a force or stroke can be applied to the baton in the direction perpendicular to the axis of the stick and it is likely that such force or stroke, in combination with the rattle, is insufficient in the extended stiffness of the stick makes.

(3) When the wall thickness of the cylindrical element is reduced for weight saving, the inclined inner surface of the outer cylindrical element is pushed away by the inclined outer surface of the inner cylindrical element, which tends to open outward when the stick with a strong force is extended. The inner diameter is therefore enlarged to allow the inner cylindrical member to slide out of the outer cylindrical member.

Furthermore, a baton with a retractable and retractable construction is described in published Japanese Utility Model 61-181996, wherein the inner and outer elements have a flush contact portion. However, in an extended state, a return stop resiliently projecting outwardly and formed by notching an inner tubular member engages the top end surface of the outer tubular member thereby preventing the inner tubular member from moving back. Therefore, a problem arises with regard to the strength of the notch.

Although an extendable and retractable mechanism is also shown in published Japanese Utility Model 63-90796, the internal construction is not described or shown in detail.

Therefore, it is an object of the present invention to overcome the aforementioned problems of the prior art and to provide construction for the extension or retraction of a baton which rattles or skews less quickly, even after repeated use and which mechanism is free is of the drawback of slipping due to a pull-out force, even at reduced weight.

Said object of the present invention can be achieved with a construction for extending and retracting a baton, comprising a number of telescopically assembled cylindrical members each of different diameter, whereby an oblique surface at the rear end of the inner cylindrical element can engage come with an oblique surface at the top end of a cylindrical element in the extended state just beyond, wherein the top end of the outer cylindrical element has an outer cylindrical peripheral surface parallel to the centerline and an inner surface with a conical oblique surface that extends toward the top end tapers and a cylindrical circumferential sliding guide surface continuous in the upper end of the conical oblique surface and parallel to the centerline, and the rear end of the inner cylindrical member has an outer cylindrical circumferential sliding guide surface parallel to the centerline e n a conical oblique surface that tapers to the top and continues into the sliding guide surface, the sliding guide surface of the outer cylindrical member being slidably contacted with the outer peripheral surface of the inner cylindrical member and the sliding guide surface of the inner cylindrical member in a sliding contact is made with the inner circumferential surface of the outer cylindrical element, respectively, while a ventilation opening is provided in at least one location of the baton.

In a preferred embodiment of the present invention, an offset is provided between the inner circumferential surface and the base of the conical bevel surface of the outer cylindrical member, and another offset is also provided between the sliding guide surface and the conical bevel surface of the inner cylindrical member such that these jumps can come into contact with each other.

In another embodiment, a wear resistant layer is applied to the inner surface of the outer cylindrical element and the outer surface of the inner cylindrical element.

In a further embodiment, a ring of a wear-resistant material and provided with a sliding guide surface is attached to the upper end of the outer cylindrical element.

In another embodiment, a wear-resistant material with a sliding guide surface is attached to the rear end of the inner cylindrical member.

In another embodiment, an angle of inclination for each of the conical engagement surfaces of the outer cylindrical element and the inner cylindrical element is determined to lie in a range from 1 ° to 2 °.

When extending and retracting, the sliding guide surface which is cylindrical shaped with respect to the outer cylindrical element is brought into face-to-face contact with the outer cylindrical surface of the inner cylindrical element, and it is cylindrical with respect to the inner cylindrical element formed sliding guide surface is brought into a face-to-face contact with the inner cylindrical surface of the outer cylindrical element, and these are guided in this state. Rattling or skewing can therefore be markedly reduced compared to the prior art construction. Furthermore, the construction causes less abrasion even after repeated extension and retraction and rattling or chipping can be suppressed to an acceptable level even after prolonged use.

Even further, when the wall thickness of the cylindrical element is reduced in order to reduce the weight, only the upper end of the outer cylindrical element is made cylindrical on the outer surface in order to locally increase the wall thickness. Accordingly, even when a high extension force is applied, the element will show a high resistance to a force that opens the top end of the cylindrical element outwardly to prevent the inner cylindrical element from slipping. In a case where the outer cylindrical element and the inner cylindrical element are engaged by staggered engagement, the anti-slip function is further enhanced. Furthermore, when the angle of inclination of each of the conical engagement surfaces of the outer cylindrical element and the inner cylindrical element is made greater than Γ, there is no danger of the inner cylindrical element slipping due to a slight manufacturing error.

The durability of the structure can be further increased significantly by providing means such as forming a wear resistant layer on the inner surface of the outer cylindrical element or the outer surface of the inner cylindrical element, attaching a ring of abrasion resistant material and a sliding guide surface at the top end of the outer cylindrical member or attaching a ring of abrasion resistant material and with a slide guide surface at the rear end of the inner cylindrical member.

In particular, since the baton in the extended state has sufficient rigidity, the present invention is particularly effective when applied to a baton with a transverse handle on which strong compressive forces can be applied.

Figure 1 is a perspective view of a retractable and retractable type baton with a transverse handle, according to a first embodiment of the present invention; Figure 2 is a vertical cross-section of the truncheon of Figure 1; Figure 3 is an enlarged cross-sectional view of a portion of the baton for explaining the slide-out and slide-in structure; Figure 4 is a partial cross-sectional side view of a modified embodiment of the truncheon shown in Figure 1; Figure 5 is a cross-sectional view of a portion of a baton extension and retraction structure according to a second embodiment of the present invention; Figure 6 is a cross-sectional view of a portion of a third embodiment of the present invention; Figure 7 is a front view of a wear resistant element in a fourth embodiment of the present invention; Figure 8 is a cross-sectional view of a portion of a fourth embodiment of the present invention; Figure 9 is a front view of a portion of an abrasion resistant member in a fifth embodiment of the present invention; and Figure 10 is a side view of the element shown in Figure 9.

Figure 1 shows, as the first embodiment of the present invention, a perspective view of a retractable and retractable baton with a transverse handle, Figure 2 is a vertical cross-section thereof, and Figure 3 is an enlarged cross-sectional view for explaining a construction for the outward - and insert.

In figure 1 the main body 1 of the baton is shown in drawn lines in a retracted state and in a dashed-dotted line in an extended state L. The main body 1 of the baton has a transverse handle 2 of a length such that it can be gripped with one hand, and which is arranged perpendicular to the main body 1 of the stick in a position slightly relative to the center to one end in the in the longitudinal direction of the main body 1 of the stick, i.e. in a position near a bulge A which is arranged at one end of the main body 1 of the stick. Thickening A comprises a cylindrical part A1 of a synthetic resin, wood or light metal through which the main body 1 of the stick is inserted.

As shown in figure 2, the transverse handle 2 of this embodiment has a support shaft 6 which extends vertically from a mounting base 5 for attachment to the main body 1 of the stick perpendicular to the main body 1 and this shaft is designed as a transverse handle of the top under-rotation type comprising a relatively rotatable lower part 7 rotatably mounted about a base end 6a of the support shaft 6, and a relatively rotatable upper part 8 rotatably mounted about an upper end 6b of the support shaft 6 and a rigid part 9 through which an intermediate portion 6c of the support shaft 6 is inserted and which is attached to the support shaft 6 in a position between the mutually rotatable upper and lower parts 7 and 8.

The main body 1 of the stick has a telescopic construction comprising a number of (in the illustrated embodiment three) cylindrical parts 25, 26 and 27 each of different diameter. The largest diameter outer cylinder 25 has inner threads 28 in the inner circumferential surface on the rear end side, which extends from the opening inward, with a plug 29 having an outer thread screwed therein, and a cap 30 as a cover in the opening at the back is screwed. In the outer cylinder 25, the outer circumferential surface includes a cylindrical surface 25a formed parallel to the central axis, and an inner circumferential surface includes an oblique surface 25d at the top, which tapers (converges). An intermediate cylinder 26 contained within the outer cylinder 25, as an inner cylindrical element, has an inclined surface 26f formed on the outer surface at the rear end, and the outer diameter thereof is slightly larger towards the opening at the rear end, such that this may engage the oblique surface 25d of the outer cylinder 25. The upper end of the intermediate cylinder 26 has an oblique surface 26d formed on the inner circumferential surface and tapering toward the top. An inner cylinder 27 received within the intermediate cylinder 26 has an oblique surface 27f on the outer surface at the rear end and the outer diameter thereof is slightly enlarged towards the opening at the rear end such that it can engage the oblique surface 26d at the top end of the intermediate cylinder 26. Internal thread is formed on the inner surface of the opening at the top end on which a cap 36 is screwed. The rear end of the inner cylinder 27 has an inner diameter such that it can engage a bifurcated spring 38 screwed to the plug 29 when the baton is retracted. The base of the cap 36 at the top end is sized to engage the top end of the intermediate cylinder 26.

More specifically, when referring to the main body 1 extension and retract construction, the stick refers to the enlarged cross section of Figure 3, it can be seen that the outer cylinder 25 as the outer cylindrical element and the intermediate cylinder 26 (an outer cylindrical element for the inner cylinder 27) are formed at their upper ends such that each of their outer surfaces 25a (26a) does not have an axial inclination angle, i.e., has a cylindrical shape with a circumferential surface parallel to the cylinder axis. On the other hand, conical inclined surfaces 25d (26d) and a cylindrical shear guide surface 25c (26c) are formed on the inner surface of each of the top end portions, with a circumferential surface parallel to the cylinder axis and continuous in the end of the conical oblique surface 25d (26d). On the other hand, each intermediate cylinder 26 has as an inner cylindrical element (inner cylindrical element for the outer cylinder 25) and the inner cylinder 27, on the outer surface of the rear end, a cylindrical slide guide surface 26e (27e) as circumferential surface parallel to the cylinder axis and a conical obliquely tapered surface 26f (27f) that extends into the slide guide surface 26e (27e), viewed from the rear end.

The shear guide surface 25c on the inner surface at the top end of the outer cylinder 25 and. the cylindrical outer circumferential surface 26a of the intermediate cylinder 26 parallel to the cylinder axis with a small play on each other, and the shear guide surface 26e on the outer surface at the rear end of the intermediate cylinder 26 and the cylindrical inner circumferential surface 25b of the outer cylinder 25 parallel to the cylinder axis. a little play on each other. The shear guide surface 26c on the inner surface at the top end of the intermediate cylinder 26 and the cylindrical outer circumferential surface 27a of the inner cylinder 27 parallel to the cylinder axis align with a small clearance, and the shear guide surface 27e on the outer surface at the rear end of the inner cylinder 27 and the cylindrical inner circumferential surface 26b of the intermediate cylinder 26 fits parallel to the cylinder axis with a little play on each other.

At least one transverse hole 31 is formed on the circumferential side of the outer cylinder 25. The transverse hole 31 may optionally also be provided in the intermediate cylinder 26 or the inner cylinder 27, on the cap 30 attached to the rear end of the outer cylinder or on the cap 36 attached to the top end of the inner cylinder 27, or the hole may be replaced through a groove or slot as long as free air can flow between the inside and the outside of the cylindrical element of the main body 1 of the stick, in order to ensure an even progression of the extension and retraction.

In this embodiment, the angle of inclination of the conical oblique surface 25d of the outer cylinder, each of the intermediate cylinder conical oblique surfaces 26d and 26f and the conical oblique surface 27f of the inner cylinder 27 is preferably selected in a range from 1® to 2®. When the angle is less than 1®, a great force is required to loosen the engagement between the inclined surfaces and receive the intermediate cylinder 26 in the outer cylinder 25 and the inner cylinder 27 in the intermediate cylinder 26, respectively, making it difficult to retract the main body 1 of the stick. However, depending on manufacturing tolerances, there may be a problem that the inner cylindrical member slips and ejects from the outer cylindrical member due to a swing force acting on the main body of the stick. On the other hand, when the angle of inclination is greater than 2 ”, the engagement between the oblique surfaces in an extended position is weakened, thus there is a risk that the engagement will come loose due to the reaction of striking an opponent, causing the main body 1 to retract from the stick . As an aside, main bodies 1 for poles were experimentally manufactured with three-stage ramp angles (tapered angles), i.e. 1®, 1.5® and 2®, and the relationship between tensile load and maximum axial compression load was determined. Test data is shown in Table 1.

As for the test method, the manufactured main body was used as a test article, and it was placed in a universal material testing device, and an axial tensile load was applied at both ends, then the test article was compressed in opposite directions, and the maximum pressure load was measured . The test was conducted by the Ehirae Prefectural Industrial Technical Center.

TABLE 1 tensile stress maximum load (kgf) load (kgf) taper taper taper 1 ° 1.5 * 2 * 100 75 50 55 150 100 100 110 200 155 130 125 250 180 215 155 300 260 185 180 350 315 310 205 400 340 315 240 450 385 310 280 500 410 390 290 550 555 400 365 600 540 470 350

When the retractable and retractable baton is used in reality, the main body 1 of the stick is swung with one hand so that the inner cylindrical element is driven outward and extended. The extension force in this case corresponds to the tensile load shown in table 1. To retract the extended main body 1 of the stick, the top end of the main body 1 of the stick is punched and pressed to receive the inner cylindrical element. The compressive force in this case corresponds to the maximum compressive load in table 1. The table shows that when the inner cylindrical element is driven out with a force corresponding to, for example, 300 kgf of the tensile load, a force of 260 kgf is required to retract it in the case of a taper of Γ but this force can be reduced to a force of 180 kgf in the case of a taper of 2 °. In other words, it is clear that a greater force must be applied for retraction when the taper is less than Γ and retraction becomes difficult when the small taper cylindrical member is driven out with great force. On the other hand, when the taper exceeds 20, the compression load further decreases and the inner cylindrical element slides back in when it is driven out with great force and the baton function cannot be achieved.

The operation will now be described.

When a centrifugal force is applied to the main body 1 of the stick by gripping the transverse handle 2 or the handle A in a state in which all cylinders 25, 26 and 27 are successively incorporated in the stick in a telescopic manner (figure 2), the intermediate cylinder 26 and inner cylinder 27 driven out and extended. In this case, the cylindrical outer circumferential surface 26a of the intermediate cylinder 26 is guided parallel to the cylinder axis, a light face-to-face contact occurs along the sliding guide surface 25c at the top of the outer cylinder 25, and the sliding guide surface 26e at the rear end of the intermediate cylinder 26 while in a slight face-to-face contact along the cylindrical inner peripheral surface 25b of the outer cylinder 25 parallel to the cylinder axis. Likewise, the cylindrical outer peripheral surface 27a of the inner cylinder 27 is guided parallel to the cylinder axis, while a slight face-to-face contact occurs along the sliding guide surface 26c at the upper end of the inner cylinder 26, and the sliding guide surface 27e on the rear end of the inner cylinder 27 is guided, while a slight face-to-face contact occurs along the inner cylindrical peripheral surface 26b of the intermediate cylinder 26, parallel to the cylinder axis. Thus, the intermediate cylinder 26 and the inner cylinder 27 can move particularly smoothly without any rattling or twisting. Furthermore, since the sliding guide surfaces 25c, 26e, 26c, and 27e are brought into face-to-face contact with each other, their termination is particularly low compared to a line contact state as in the prior art, even when the stick is extended for a long time repeatedly extended and retracted, so that the service life can be greatly increased.

In the fully extended state, the inclined surface 26f at the rear end of the intermediate cylinder 26 driven out of the outer cylinder 25 engages the inclined surface 25d at the top end of the outer cylinder 25, and the inclined surface 27f at the rear end of the intermediate cylinder 26 driven inner cylinder 27 engages the inclined surface 26b at the upper end of the intermediate cylinder 26 and is retained against slipping. Upon engagement, a strong impact force occurs on the outer cylinder 25 when the outer cylindrical element (and the inner cylinder 26) contact each other at the inclined surface 25d (and 26d) at the top end portion, and the force component along the oblique surface is applied in the outward opening direction. Since the outer surface of the outer cylinder 25 (and the inner cylinder 26) is made cylindrical up to the top end, so that the wall thickness at the top end that could lead to deformation in the known construction is locally reinforced, it becomes less in the present invention deformed even when a great force is applied in the direction of the outward opening. Therefore, when the main body 1 of the stick is driven out with a great force, it can be prevented from slipping. The wall thickness for each of the cylinder elements can be reduced as a whole to save weight.

Figure 4 shows a modified construction of the first embodiment, in which a protection part 40 is attached to the main body 1 of the stick instead of the transverse handle. The extension and retraction of the main body 1 is the same as in the first embodiment.

Figure 5 shows a portion of a structure for extending and retracting the main body 1 of the stick in a second embodiment of the present invention.

In this embodiment, a breast 51 is formed between an inner circumferential surface 25b (26b) at the top end and the base of an inclined surface 25d (and 26d) of an outer cylinder 25 as an outer cylindrical element (and an intermediate cylinder 26), while another chest 52 that can engage with the chest 51 is disposed between a sliding guide surface 26e (27e) and an inclined surface 26f (27f) of the intermediate cylinder 26 as an inner cylindrical element (and an inner cylinder 27). This modified embodiment has the advantage that a further improved effect is obtained for preventing slippage by engaging the breasts 51 and 52 on one another.

Figure 6 shows part of a third embodiment of the present invention.

In this embodiment, a ring 55 of a wear-resistant material and with a sliding guide surface 25c (26c) is attached to the top end of an outer cylinder 25 as an outer cylindrical element (and an intermediate cylinder 26). As the abrasion resistant material, a titanium alloy or the like other hard metal or a low friction synthetic resin such as a fluorine resin is preferred.

Figures 7 and 8 show part of a fourth embodiment of the present invention.

In this embodiment, a ring 56 made of the same wear-resistant material as described above has a slide guide surface 26e (27e) mounted and fixed at the rear end of an intermediate cylinder 26 as the inner cylindrical member (and an inner cylinder 27). by a screw clamp ring 57. The sliding guide surface 26e (27e) protrudes spherical in a number of sections (four sections in the embodiment shown) from the outer peripheral surface of the wear-resistant ring 56.

Figure 9 shows a fifth embodiment according to the present invention, which differs from the fourth embodiment shown in Figures 7 and 8 in that the sliding guide surface 26e (27e) of the wear-resistant ring 49 is designed as a cylindrical surface.

Each of the third to fifth embodiments has the advantage of significantly increasing durability by manufacturing the sliding guide surface of the wear-resistant material separate from the cylindrical member.

Although not shown in the drawings, the inner surface of the outer cylinder 25 as the outer cylindrical element and the intermediate cylinder 26 and the outer surfaces of the intermediate cylinder 26 and the inner cylinder 27 as the inner cylindrical element may be provided with a wear resistant layer, for example by applying a nitrification treatment or coating with a titanium alloy to increase durability.

As described above, with the retractable and retractable baton according to the invention, since a sliding guide surface at each of the ends of the inclined surfaces of the outer cylindrical element and the adjacent inner cylindrical element over the portion over which they engage in a flat-to-flat contact with the circumferential surface of the cylindrical element, achieves a beneficial effect that a particularly uniform extending and retracting action is obtained and reduction of abrasion at the end of the inclined surface even after repeated use, thereby rattling or chipping is avoided for a long time Since the wear resistance of the sliding guide surface and its contact surface has been improved, an effect can be obtained which greatly improves the durability compared to the known construction. Furthermore, since the outer surface at the top end of the outer cylindrical element is cylindrical and the inner surface thereof tapers to the top end with the conical bevel surface and a cylindrical sliding guide surface extends to the top end of the conical bevel surface, the wall thickness can be increased locally at the top end thereby achieving a beneficial effect that the top end of the outer cylindrical member is less opened when extended, thereby preventing the inner cylindrical member from slipping even when a strong impact is applied to the top end of the outer cylindrical member. Furthermore, since the staggered or breasts are formed on the engagement portion between the inner and outer cylindrical elements, thereby limiting the angle of inclination of each of the inclined surfaces, a further improved anti-skid effect can be achieved.

In particular, when the extension and retraction structure of the present invention is used with a truncheon with a transverse handle, sufficient stiffness in the extended state of the truncheon can be obtained to achieve high reliability.

Claims (8)

Construction for extending and retracting a baton, comprising a plurality of telescopic cylindrical elements of different diameters, wherein in an extended condition, an inclined surface at the rear end of an inner cylindrical element can be engaged with an inclined surface at the top end of a cylindrical element outside of it, the top end of the outer cylindrical element having a cylindrical outer peripheral surface parallel to the cylinder axis and an inner surface having a conical oblique surface tapering to the top end and a cylindrical circumferential sliding guide surface extending into the top end of the conical oblique surface and parallel to the cylinder axis, and wherein the rear end of the inner cylindrical element has a cylindrical circumferential sliding guide surface parallel to the cylinder axis and a conical oblique surface tapering to the top end and extends into the sliding guide surface, the sliding guide surface of the outer cylindrical element being slidably contacted with the outer peripheral surface of the inner cylindrical element and the sliding guide surface of the inner cylindrical element being slidably contacted with the inner peripheral surface of the outer cylindrical element. The baton extension and retraction structure of claim 1, wherein a breast is formed between the inner circumferential surface and the base of the conical bevel surface of the outer cylindrical member, and another breast is formed between the sliding guide surface and the conical bevel surface of the inner cylindrical element. The construction for extending and retracting a baton according to claim 1 or 2, wherein a wear resistant layer is formed on the inner surface of the outer cylindrical element and the outer surface of the inner cylindrical element. A baton extension and retraction structure according to any one of claims 1 to 3, wherein a ring of a wear resistant material and with a sliding guide surface is attached to the upper end of the outer cylindrical element. The baton extension and retraction structure of any one of claims 1 to 4, wherein a ring of a wear-resistant material and with a sliding guide surface is attached to the rear end of the inner cylindrical member. The baton extension and retraction structure of any one of claims 1 to 5, wherein the angle of inclination of each of the conical engagement surfaces of the outer cylindrical element and the inner cylindrical element is within a range of 1e and 2 °. The construction for extending and retracting a baton according to any one of claims 1 to 6, wherein the baton is a baton with a transverse handle. The construction for extending and retracting a baton according to any one of claims 1 to 7, further comprising a ventilation hole in at least one location of the baton.