The present invention relates to the technical field of handcuffs made of one or two bracelets linked to each other and intended to be attached to one or two wrists of an individual. The described handcuffs are designed to facilitate the handcuffing of an individual.
Usually handcuffs include a first half-bracelet rotating around a second half-bracelet, the first half-bracelet being equipped at its open end with a ratchet interlocking with the internal pawl. The pawl is located inside the handcuffs casing and is usually interdependent from the second half-bracelet. The locking teeth prevent the first half-bracelet from unlocking when the ratchet interlocks with the internal pawl. The handcuffs are thus locked around the wrist of an individual or locked around an object in order to be fixed to him. The length of the ratchet is designed so that the handcuffs perfectly adjust themselves to wrists of various sizes as well as to ankles. The casing includes means for locking and unlocking.
These kinds of handcuffs suffer from several disadvantages. First of all, two hands are needed to cuff a member to be restrained. One hand must hold the handcuffs casing and the second half-bracelet against the member to be restrained, while the other hand must adjust the first half-bracelet, pushing the ratchet in deeper or shallower. During this manipulation, the operator is at the risk of aggressive behavior by the person to be restrained. If the arrested person resists, classic handcuffs cannot be used. Also these handcuffs require that the member to be restrained is not held to the body or against any surface. In effect, the first half-bracelet needs room to close freely to the second.
Moreover, in order to remove the handcuffs, the operator has to hold them in one hand, open them with the key and then release the blocked member. All these manipulations make the use of handcuffs tedious and not well suited to situations sometimes requiring urgency and speed.
Therefore, it would be desirable to provide handcuffs without these disadvantages and equipped with a means of handcuffing with one hand.
According to one embodiment of the invention, handcuffs for gripping a member comprise a first half-bracelet, a second half-bracelet configured to close with the first half-bracelet around the member by pivoting around a first axis, a locking mechanism including a sensor assembly configured to block opening of the first half-bracelet and the second half-bracelet in response to pressure from the member, and an opening mechanism configured to open the first half-bracelet open relative to the second half-bracelet in the absence of the member applying pressure to the sensor.
According to an aspect of the invention, the first half-bracelet has a central part located around the first axis that includes a clasp having first teeth configured to engage with second teeth of an opening lever, the first and second teeth being maintained against each other by a pull-back spring.
According to another aspect of the invention, the opening lever is configured to release the teeth of the clasp while pivoting on a second axis against the action of the spring.
According to another aspect of the invention, the opening lever is configured to release the teeth of the clasp while pivoting on a second axis against the action of the spring.
According to another aspect of the invention, the opening lever pivots around the second axis against the action of the spring by the action of an opening component.
According to another aspect of the invention, the opening lever pivots around the second axis and against the spring in response to movement of a key.
According to another aspect of the invention, the handcuff further comprises a wheel at the end of the second half-bracelet configured to roll around the member to be blocked and so preventing the second half-bracelet to get caught on clothing or skin.
According to another aspect of the invention, the handcuff is coupled to another handcuff by means of rigid, flexible or articulated connection.
According to another aspect of the invention, the opening mechanism includes a clutch, a blocking notch and a spring configured to allow the handcuff to remain open yet prevent unintended closing.
According to another aspect of the invention, the locking mechanism includes a manual closing element in the form of a trigger, and the locking mechanism is configured to manually prevent unintended closing. The trigger may be configured to be actuated by an operator's finger.
According to another aspect of the invention, the locking mechanism includes a locking pawl and the first half-bracelet includes a notch into which the locking pawl is inserted against a return spring, whereby the first half-bracelet may be locked together in a closed position with the second half-bracelet.
According to another aspect of the invention, the opening mechanism includes a release lever configured to pivot around the first axis, and the opening mechanism includes a notch configured to receive by a pin of said locking pawl under action of said return spring to maintain the lock in an open position, whereby pressure from the member when disposed between the first and second half-bracelets displaces the release lever and turns the locking pawl around an axis to disengage the pin from said notch.
According to another aspect of the invention, the first half-bracelet includes an opening lever configured to be blocked by the opening mechanism while the first and second half-bracelets are locked in a closed position. In this embodiment, the first half-bracelet have teeth configured to be retained against teeth of the opening lever under force applied by a return spring.
According to another aspect of the invention, the opening lever is configured to disengage the teeth of the first half-bracelet by turning against the action of a spring by means of a key received in a keyhole.
Goals, objects and characteristics of this invention will appear more clearly after reading the following description and referring to the following drawings:
One end of the handcuff's casing 1 extends to second half-bracelet 11. Note: the second half-bracelet 11 can be interdependent or not from the handcuff's casing 1.
In this embodiment, the body of the handcuff is preferably made of two separate, nearly identical components with a locking-unlocking mechanism disposed in-between. A moving clasp 2 is located between the handcuff's two body components 1. The clasp 2 is S-shaped, pivots around an axis 100 located in a central area, and is fixed to the casing of the handcuff. The curved interior of a lower part 21 of the clasp 2 forms a first half-bracelet.
The upper part of the clasp 2 slides into a holding housing 8 and is held within by a powerful pull-back spring 200. In its upper part, the clasp 2 is attached to a clutch 3 that rotates around the axis 100. The clutch is placed in such a way that it is superimposed on the curved outside of the upper part of the clasp 2. The clasp 2 has inclined teeth 22 at the axis 100, which interact with an opening lever 4. The opening lever 4 rotates around an axis 101 fixed to the carcass. The teeth of the opening lever 4 are maintained against the teeth 22 of the clasp 2 due to a spring 201, so that as long as two teeth are synchronized, the first half-bracelet can only turn around the axis 100 in the direction that brings it to the first half-bracelet 11, therefore in the direction which closes the handcuff. In order to disengage the teeth 22 and 41 and thus allow the clasp to turn around the axis 100 in the direction away from the first half-bracelet 11, therefore opening the handcuff, the opening lever 4 must push against the pull-back spring 201.
The opening component 5 is laid out and adapted so that, when it is pushed against a pull-back spring 202, due to a manual control 52, it moves the lever 4, which rotates around its axis 101. This action disengages the teeth in opposition of the clasp 2 and the opening lever 4. The clasp 2, now no longer being blocked by the lever 4, is forced by the spring 200 into a circular motion around the axis 100 of the opening direction. And so the handcuff is ready to be used. The hand control 52 is part of the opening component and is located outside the handcuff casing 1 in order to be easily handled by the operator.
Open at its maximum, the ratchet 6 rotating around an axis 103 fixed to the handcuff casing penetrates into the appropriate notch 23 of the clasp 2. The ratchet 6 is kept in this position due to a pull-back spring 203. This interaction prevents any inopportune closing of the handcuff especially in the open position, when trying to place it between the member and a surface.
Once opened, the handcuff is ready for use. The operator holds the handcuff in one hand, directs it towards the member to be blocked so it passes between a wheel 12 and the end of the clasp 2. The wheel 12 turns freely around the axis 102 fixed at the end of second half-bracelet 11. The turning movement of the wheel 12 avoids the second half-bracelet to get caught up in the skin, clothing or other obstruction.
A significant advantage of the just-described structure is that it allows a frontal gripping of a member to be restrained.
The action of pushing the member to be restrained towards the clutch 3 moves the clutch against pin 61 of the blocking pawl 6. This pushing action makes the ratchet 6 turn clockwise around its axis 103, while being opposed to the pull-back spring 203 and releases the clasp 2. As long as the user continues to press on the member to be restrained, the clasp 2 also starts to turn while being opposed to the spring 200 so that first half-bracelet 21 is closing around the member to be blocked. Any attempt to reopen the handcuff is then prevented by teeth 22 of the clasp 2 synchronized with the reversed teeth of the opening lever 4. The operator gradually pushing the member closes the handcuff until the first half-bracelet is properly adjusted around it, tightened but without wounding it. The applied force from the member pushes onto a sensor 7, which picks up this action. This has the effect of turning it around the axis 104 fixed at the handcuff casing 1 and pushing against the pull-back spring 204 until the blocking pin 71 of the sensor is synchronized with the blocking pin 51 of the opening component 5.
In closed position, the first half-bracelet is on the second half-bracelet so that their ends cross. Preferably—the end of the second half-bracelet being made of two separate parts with a gap in between—when in closed position the first half-bracelet closes into this space.
This embodiment can be implemented in other ways. In a second embodiment, neither a clutch 3 nor a pull-back spring 200 is utilized. In this alternative, a closing command activated by the operator's forefinger (as depicted
In another embodiment, the handcuff's casing can be extended at its other end by a handle 13 as shown in
The body of the handcuff 1 can be extended to form a second in order to be able to block two members of a person or to hang the handcuff to a fixed object. The two handcuffs can be coupled together by means of rigid or articulated connection such as a pivoting connection around an axis, a chain, etc.
Handcuffs according to the invention can be made from various appropriate materials, including, for example, metal alloy, aluminum alloy, plastic or synthetic material.
A principal advantage of handcuffs according to the above-described embodiments is that they can be used even if the member to be blocked is against the body or another surface. Moreover, handcuffing an individual does not require the user to use his second hand to close the first half-bracelet around the member to be blocked.
Although the invention is described in its principal application of blocking the member of an individual, one could consider its usage in any other application but within the framework of this invention.
Number | Date | Country | Kind |
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09/00680 | Feb 2009 | FR | national |