The field of the invention relates to telescopically extending and locking batons. More particularly, the field of the invention relates to extendable and lockable/releasable police or military batons with improved durability and reliability.
Batons for use by the police and military are well known. Such batons can be of great value in close quarters or where non-lethal force is necessary or warranted. In many cases, batons used by the police or military are compact to carry and easy to deploy. Such batons may be constructed of one or more telescoping sections including a handle and more or more sections that slide into the handle.
A three-section telescoping baton with locking clutches and a button release is disclosed, for example, in U.S. Pat. No. 9,677,843, which is incorporated by reference. These batons are advantageous because they may be deployed to an extended and locked position and unlocked and stowed with one hand. Referring to
While very convenient to deploy and stow, there are some disadvantages with such locking clutch designs. The ends of the baton sections where the locking clutches are located may be weakened by the slots for the clutch plates. Referring to
Another issue with known designs is that elastomeric O-rings are used to reduce play between sections. Such elastomeric O-rings must be treated with oil or other lubricant to provide a low friction interface. However, the oil or lubricant may attract dirt and contamination, or be wiped off the mating surfaces completely. If left unserviced, the oil or lubricant may dry up, seizing the baton sections against each other, rendering the baton inoperable, to the detriment of the user.
An extendable baton is provided, having a base section, at least one extendable section and a control rod connected to a release button. The base section may be tubular and have a lengthwise axis, a first annular recess on an inner surface of a distal end and a release button on a proximal end, the first annular recess having a width. The extendable section may also be tubular and be dimensioned to nest inside the base section coaxially with the longitudinal axis. The extendable section includes a locking clutch on a proximate end, the locking clutch including a single slot disposed on the proximate end of the extendable section, a clutch plate disposed at least partially within the slot, the clutch plate including a locking portion having an arc that fits within the slot and a thickness that fits within the width of the first annular recess, and a control aperture portion having a control aperture, a guide cap disposed on the proximate end of the extendable section including a guide aperture, and at least one spring disposed to bias the clutch plate outwardly from the slot of the extendable section. The control rod is insertable through the guide and control apertures to retract the clutch plate toward the slot of the extendable section when the release button is depressed. When the extendable section is extended from the base section, the control rod is withdrawn from the aperture, the spring biases the clutch plate outwardly from the slot of the extendable section, and the locking portion of the clutch plate engages the annular recess.
It has been found that reducing the number of semi-circular clutch plates from two to one provides several advantages relating to the durability of the baton and to the cost the of manufacture, while still providing sufficient locking performance. The single slot section end has better resistance to damage from shock loading. The base section may comprise a handle of the baton.
The extendable baton may have a plurality of extendable sections having locking clutches. For example, the at least one extendable section may comprise a first extendable section having a second annular recess on an inner surface of a distal end of the first extendable section, and the extendable baton may further comprise a second extendable section. The second extendable section may be a smaller version of the first extendable section and may be tubular and dimensioned to nest inside the first extendable section coaxially with the longitudinal axis. The second extendable section also includes a second locking clutch on a proximate end, the second locking clutch being controlled by the same control rod and being dimensioned to engage the second annular recess when the second extendable section is extended.
The clutch plate disposed at least partially within the slot may consist of a single clutch plate. The locking portion of the clutch plate may have a radius that substantially matches the proximal end of the extendable section. The aperture may be located at a center of the radius. The control aperture portion of the clutch plate may have a thickness that is substantially the same as the locking portion of the clutch plate.
The slot may have an arc which is less than half the circumference of the proximal end of the extendable section. When the control rod is inserted through the aperture to retract the clutch plate, the clutch plate may be retracted completely within the slot.
The extendable baton may further include a plastic ring disposed in the distal end of the base section to provide a low friction bearing surface for the extendable section.
In one example, the guide cap is formed from a high impact thermoplastic and at least one spring seat is a molded into the guide cap. In another example, the guide cap is formed from metal for additional impact damage resistance. In another example, a portion of the section end opposite the clutch plate is reinforced for additional impact damage resistance.
In one particular example, an extendable baton is provided. The extendable baton has a handle section, first and second extendable sections and a control rod connected to a release button. The handle section may be tubular and have a lengthwise axis, a first annular recess on an inner surface of a distal end and a release button on a proximal end, the first annular recess having a width. The first extendable section may also be tubular and be dimensioned to nest inside the handle section coaxially with the longitudinal axis. The first extendable section includes a first locking clutch on a proximate end and a second annular recess on a distal end, the first locking clutch including a single slot disposed on the proximate end of the first extendable section, a clutch plate disposed at least partially within the slot, the clutch plate including a locking portion having an arc that fits within the slot and a thickness that fits within the width of the first annular recess, and a control aperture portion having a control aperture, a first guide cap disposed on the proximate end of the first extendable section including a guide aperture, and at least one spring disposed to bias the clutch plate outwardly from the slot of the extendable section. The second extendable section may also be tubular and be dimensioned to nest inside the first extendable section coaxially with the longitudinal axis. The second extendable section includes a second locking clutch on a proximate end, the second locking clutch including a single slot disposed on the proximate end of the first extendable section, a clutch plate disposed at least partially within the slot, the clutch plate including a locking portion having an arc that fits within the slot and a thickness that fits within the width of the second annular recess, and a control aperture portion having a control aperture, a second guide cap disposed on the proximate end of the second extendable section including a guide aperture, and at least one spring disposed to bias the clutch plate outwardly from the slot of the extendable section.
The control rod is insertable through the guide apertures and control apertures to retract the clutch plates toward their respective slots of the extendable sections when the release button is depressed. When the extendable sections are extended from the handle section, the control rod is withdrawn from the apertures, the springs bias the clutch plates outwardly from the slots of the extendable sections, and the locking portions of the clutch plates engage their respective annular recesses. This may happen sequentially or simultaneously.
In one example, the first guide cap is formed from a high impact thermoplastic and at least one spring seat is a molded into the guide cap, the second guide cap is formed from metal, and in the second extendable section, a portion of the section end opposite the clutch plate is reinforced for additional impact damage resistance.
While embodiments can take many different forms, specific embodiments thereof are shown in the drawings and will be described herein in detail with the understanding that the present disclosure is to be considered as an exemplification of the principles hereof, as well as the best mode of practicing same. No limitation to the specific embodiment illustrated is intended.
In general, the baton is constructed of one or more tubular sections. The outermost section may comprise a base section, such as a handle section 12. In a stowed position (
In a deployed state (
Once deployed, a respective spring-loaded locking clutch (discussed below) locks each extended section 14, 16 to the directly adjacent next larger section. In this regard, the locking clutch locks the inner section 16 to the intermediate section 14 (or to the handle section 12 if no intermediate section is used).
The baton 10 may include a release button 24 on the proximate end of the handle section 12. The release button 24 operates a control rod 34. The control rod 34 extends between the release button 24 and each of the locking clutches. As the baton 10 is deployed and each section locks to the next section, the release button 24 may pop out of the handle section 12 as the control rod is disengaged from the locking clutches. To stow the baton, a user simply activates the button (pushing it back into the handle) to cause the control rod 34 to retract the locking clutches and then pushes the inner section 16 (and any intermediate sections) back into the handle section 12 thereby returning the baton 10 to the stowed position or state.
The clutch plate 38 may include a locking portion 38a and a control aperture portion 38b. The locking portion may comprise an outer edge defined by an arc (partial circumference of a circle) and a radius that is substantially the same as the distal end of intermediate section 14. The length of the arc is such that the clutch plate substantially matches the slot 35. The control aperture portion may have an aperture 36 at a center of the radius of the arc. The control aperture portion may be the same or substantially the same thickness as the locking portion. While the term “semicircular” may be used to describe the shape of clutch plate 38, the arc need not comprise an exact half circle. The arc of a clutch plate may be less than half a circumference of the section end in which it is located.
The single slot 35 is cut into the distal end of the intermediate section 14 to receive a single clutch plate 38 of the locking clutch 26. Once inserted into the slot 35, an aperture 36 may be engaged by the control rod 34 to secure the clutch plate 38 within the slot 35.
Also, because only one slot 35 is provided, a side of the section 14, 16 opposite slot 35 may be reinforced to provide even more resistance against damage from shock loading.
In the illustrated example, the locking clutch 26 further comprises a guide cap 64. Guide cap 64 may be formed from a thermoplastic, such as polyoxymethylene (sold under the brand name Delrin). In some embodiments, the thermoplastic comprises high impact polypropylene for additional impact damage resistance. Guide cap 64 includes an aperture 65 to guide the control rod 34 and recessed seats 48 for springs 42, 44. The guide cap 64 provides the advantages of reducing machining required for spring seats and improving the retraction action of the baton by guiding the control rod to the aperture of the clutch plate. In some embodiments, the guide cap 64 is retained in place by the springs 43,44, and clutch plate 38. In other embodiments, the guide cap is held in place by adhesive or a friction fit.
Included within the clutch plate 38 are a set of spring seats 46 that receive the other ends of the springs 42, 44. Because there is only one clutch plate 38, the control aperture portion of clutch plate 38 may be made at the full thickness of the locking portion of the clutch plate which engages the recess 30, thereby improving resistance to damage from shock loading.
The inner section 16 has a similar single slot and locking clutch 28, including clutch plate 40 and guide cap 66 sized appropriately to a diameter of inner section 16 and recess 32. The configuration and operation of the components of locking clutch 28 may be the same as or similar to locking clutch 26, and for purposes of brevity are not separately illustrated in exploded view.
In some embodiments, as illustrated in
In some embodiments, a combination of metal and thermoplastic guide caps are used within the same baton. For example, guide cap 66 on inner section 16 may be fabricated as a metal component, and guide cap 64 on intermediate section 14 may be fabricated as a thermoplastic component. Such an arrangement optimizes strength at the striking end of the baton and reduced cost in the middle of the baton.
Compression rings 60, 62 (
During use, the control rod 34 extends through apertures 36 thereby holding the apertures 36 in coaxial alignment with the baton sections 14, 16. The springs 42, 44 of each locking clutch 26, 28 are held in compression. So long as the control rod 34 extends through the apertures 36, an outer edge of the locking clutch 26, 28 is held even with (or slightly within) an outer circumference (outside annular edge) of the respective sections 14, 16. When the control rod 34 is withdrawn from the apertures, the springs bias the clutch plates 38, 40 outwards towards an inner surface of the next outer section, and eventually into the recesses 30, 32 when fully extended, thereby locking each inside section of the baton to the next closest outer section that is directly adjacent the inside section. In some embodiments, the surface of control rod 34 is textured or knurled. This provides a degree of control over a level of friction between the control rod 34 and the apertures 36 of the clutch plates 38, 40 to avoid inadvertent deployment. This may be advantageously combined with the low friction compression rings 60, 62 to achieve a baton that deploys reliably with reduced maintenance, yet does not inadvertently deploy if held tip down.
As the clutch plates 38, 40 move radially outwards, the apertures 36 are no longer in axial alignment with the sections 14, 16. However, even with the clutch plates 38, 40 extended, the predominant axis 18 of the baton sections still passes through the apertures 36, albeit off center. This allows a tapered end 54 of the control rod 34 to later re-engage and retract the clutch plates 38, 40.
In order to deploy the baton 10, a user may grasp the handle section 12 on one end and the baton tip 16a on the distal end of the inner section 16 and pull outwards. The outwards force may first cause the inner section 16 to begin sliding outwards relative to the intermediate section 14 and handle section 12. Since the control rod 34 is attached to the handle section 12, the outward movement of the inner section 16 causes the control rod 34 to begin to withdraw from the aperture 36 of the locking clutch 28. Immediately before the locking clutch 28 reaches the recess 32, the control rod 34 exits the aperture 36 of the locking clutch 28. This allows the springs to push the semicircular plate 38 outwards into the recess 32, thereby locking the first end of the inner section 16 to the second end of the intermediate section 14.
If the user continues to pull, the inner section 16, locked to intermediate section 14, causes the intermediate section 14 to begin moving outwards away from the handle section 12. As the intermediate section 14 moves outwards, the control rod 34 begins to withdraw from the locking clutch 26 of the intermediate section 14. Immediately before the locking clutch 26 reaches the recess 30, the control rod 34 exits the aperture 36 of the retainer of the intermediate section. This allows the springs of the locking clutch 26 to push the semicircular plates into the recess 30, thereby, locking the intermediate section to the handle section 12.
As the intermediate section locks to the handle section 12, the release button 24 may pop out of the end of the handle section 12. In one example, as the control rod 34 exits the locking clutches, a control rod 34 spring 52 (
In order to stow the baton 10, the user may first depress or otherwise activate the release button and then push the baton tip 16a towards the handle section 12. Depressing the release button 24 causes the control rod 34 to re-enter and align the aperture 36 of the locking clutch 26, thereby retracting the locking clutch plate 38 from recess 30. More specifically, a tapered distal end of the control rod 34 enters the aperture 36 contacting the aperture along one edge. As the tapered end enters the aperture, the sliding contact on the taper pushes the aperture into alignment by forcing the semicircular clutch plate inwards thereby realigning the aperture 36 with the control rod 34 and predominant axis 18 of the sections 14, 16 thereby retracting the clutch plates 38 and releasing the locking clutch 26. This allows the intermediate section 14 to be nested within handle section 12. As intermediate section 14 is fully retracted, if the user continues to depress button 24, the tapered end of the control rod 34 with push into alignment clutch plate 40 of locking clutch 28, retracting clutch plate 40 from recess 32. This allows the inner section 16 to be nested within intermediate section 14.
The locking clutches of the present invention offer significant advantages over prior batons. For example, the section ends incorporating the locking clutches are stronger than opposing locking plate designs due to only one slot 35 being cut into the section end. The portion of the section end opposite slot 35 may also be reinforced for additional strength and damage resistance. Additionally, the individual locking clutch plates 26, 28 are stronger than dual opposing locking plate designs because the full thickness of the plate may be maintained throughout the entire locking clutch plate. Thus, reliability and resistance to failure during use in the field is greatly improved. Additional benefits of the present invention include reduced cost of manufacture because there are fewer components to make or purchase, and reduced labor for assembly.
From the foregoing, it will be observed that numerous variations and modifications may be effected without departing from the spirit and scope hereof. It is to be understood that no limitation with respect to the specific apparatus illustrated herein is intended or should be inferred. It is, of course, intended to cover by the appended claims all such modifications as fall within the scope of the claims.
Filing Document | Filing Date | Country | Kind |
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PCT/US2019/051242 | 9/16/2019 | WO | 00 |
Number | Date | Country | |
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62732745 | Sep 2018 | US |