The present design relates generally to the field of personal restraint and securing of individuals, and more specifically to handcuffs used in law enforcement, military, corrections or private security, wherein enhanced features make removing the handcuffs more difficult for the restrained individual.
Handcuffs have been used for centuries to restrain individuals in various scenarios, including but not limited to prison or correctional facility situations. Use and construction of handcuffs and similar restraints are well known, and handcuffs are generally accepted as an effective restraint system for use by law enforcement, military personnel, security officers and various other entities worldwide. Handcuffs are a standard issued item of police equipment utilized by every major law enforcement agency in the world, and handcuffs and/or related restraints are currently in use by police officers, corrections officers, private security officers, military personnel, and so forth. The same may be said for other restraining devices, including but not limited to handcuffs, leg chains, waist chains, finger cuffs, and any manner of mechanisms used to restrain a person's wrists, hands, arms, ankles, legs, feet, or any or other body part. As used herein, all these restraining devices will be generally referred to as “handcuffs” and the teachings herein may apply to other restraining devices while illustrated for use in, for example, restraining an individual by his or her wrists.
Handcuffs have for decades employed a standard ratchet teeth type locking system wherein a standard universal handcuff key is needed to unlock them. Handcuffs are a critical piece of law enforcement equipment and very few viable alternatives to standard handcuffs exist. Although many manufacturers have attempted to create a more secure handcuff, these have largely been commercially unsuccessful and thus the same traditional handcuff style used decades ago is still typically in use today.
The standard handcuff in use by law enforcement today utilizes a bracelet type design placed around a wrist and secured via a ratchet which is then locked into place. The teeth of the ratchet engage the teeth of the spring-loaded pawl located inside the bracelet and when the pawl is forced against the ratchet, the two sets of teeth are locked together. To release the handcuffs, the pawl must be disengaged from the ratchet teeth, which is accomplished with the use of a universal handcuff key. The handcuff key is rotated to disengage the primary lock. The design of the ratchet teeth and pawl allows for free movement of a piece called a single strand when tightening the handcuffs, but prevents the single strand from loosening unless the pawl is depressed so that it may no longer engage the ratchet teeth.
Each wrist of the wearer is secured with an individual handcuff connected to another handcuff via a small chain, hinge, solid locking component, or other method. This assembly is commonly referred to as a set of handcuffs, a pair of handcuffs, “handcuffs” or any other derivative phrase indicating two or more handcuff portions secured together to form a unit capable of securing two or more appendages of a wearer.
A universal handcuff key is used to manipulate a traditional double lock bar mechanism, which moves laterally under the pawl. The double lock bar can be set to prevent the pawl from being depressed thereby locking the single strand into place. Handcuffs with double lock bars have a detent, which when engaged, stops the cuff from ratcheting tighter and prevents the wearer from over-tightening the cuffs. Tightening the handcuff ratchets could be intentional or may occur unintentionally when pressure is applied to the single strand ratchet. As a result, handcuffs may cause nerve damage or loss of circulation in a wearer's hands due to over-tightening. Additionally, some wearers may tighten the handcuffs in order to attempt an escape by utilizing lock picking tools or have an officer loosen the handcuffs where the wearer subsequently attempts to escape while the handcuffs are loosened. Double locking the handcuffs make picking handcuff locks more difficult.
These traditional and current handcuff designs can be susceptible to countermeasures and escape attempts such as lock picking. Lock picking is the practice of unlocking a lock by manipulating various components of the locking device without the use of the original key. For purposes of this document, the term “lock picking” will broadly be used to describe various countermeasures utilized in an attempt to defeat the security capabilities of handcuffs or related restraints.
Handcuffs may be opened by, for example, utilizing a handcuff key or lock pick, slipping the hands out of the handcuffs when the hands are smaller than the ratchet openings, releasing the pawl with a shim, or breaking the handcuff chain commonly known as “handcuff breaking.”
A significant issue with commercial handcuffs today is the ability to unlock the cuffs using a single commonly available universal handcuff key. The universal handcuff key is simple in its design and encompasses a shaft, a bow which is used to grip the key, a single bit or tooth which engages the pawl of the handcuffs to release the single strand and a peg used to engage the double locking mechanism. Due to the simple design of the key and corresponding locking mechanism inside the common handcuff, significant vulnerabilities exist in the design.
Many law enforcement officers utilize handcuffs designed for use with a universal handcuff key due to needs for operational and field expediency. Handcuffs are often placed on suspects and physical custody of the individual(s) is transferred to other law enforcement personnel. The need to have a common key is important to ensure efficiency when cuffing, uncuffing or transporting a prisoner whether it is in a patrol environment, the courts, a jail system, prisons or any other setting. Further, emergency situations can sometimes arise when releasing the individual is required for the individual's safety, and an unusual or remote key could potentially result in harm to the individual.
Due to this commonality of the universal handcuff key design, suspects and other non-law enforcement related personnel sometimes carry handcuff keys on their person in anticipation of defeating handcuff locking mechanisms. Variations of the universal handcuff key are often hidden and kept by criminals and inmates on their person with the intent to escape and/or assault someone. Handcuff keys have been known to be built into devices and/or attached to designs to be worn on a person's clothing or body wherein they are not readily recognized as a handcuff key. These surreptitious handcuff keys can then be quickly deployed and utilized to escape or attack an officer or other individual nearby.
Additionally, a simple pin or piece of metal (or similar object) can be utilized to pick the primary handcuff locking mechanism, or a shim can be forced between the single strand ratchet teeth and the pawl, thereby releasing the handcuffs. Books and instructional videos are readily available demonstrating various ways to open handcuffs—even by the wearer. These methods for picking standard handcuffs can be learned and completed with the use of a single hand by individuals even while handcuffed with their hands behind their backs.
Lock breaking refers to a method whereby the handcuffs are twisted in such a manner as to cause undue torsion on the small chain connecting the two handcuff assemblies. Additional tension is then exerted with force by the wearer so that the chain breaks thereby freeing a suspect's hands. Such a vulnerability is also undesirable.
Certain designs have improved on prior versions of traditional handcuffs, inhibiting the ability for the wearer to defeat the locking mechanism. One such improved design includes the variations presented in U.S. Pat. No. 9,551,170, inventor Kresimir Kovac, issued Jan. 24, 2017, assigned to the assignee of the present application. However, traditional and even more modern handcuff solutions can have issues. It has been observed that in certain instances wearers of handcuffs can strike a cuff against a hard surface, in some cases repeatedly, and defeat a single or double lockbar arrangement. Additionally, on occasion ratchet teeth provided on handcuffs can wear out or wear down such that the cuffs can be rendered inoperable or unusable.
There is a need for enhanced security handcuffs which provide greater security and an inability for them to be opened by the wearer. Security handcuffs should be simple to operate, should preferably have a generally similar form factor as current designs, and still utilize a universal handcuff key. Handcuffs should be extremely difficult, if not impossible, to open by the wearer of the handcuffs even if they are in possession of the handcuff key or other lock picking device. Handcuffs should nevertheless be capable of easily being unlocked by an officer, utilizing a universal handcuff key, while at the same time avoiding the design limitations and vulnerabilities associated with earlier designs.
According to a first embodiment of the present design, there is provided a handcuff comprising a handcuff single strand comprising ratchet teeth, a pair of buttons on opposing sides of the handcuff, and a spring configured to receive rotational force and cause rotation of a first rotating element. Rotation of the first rotating element rotates a second rotating element, releasing the second rotating element from the ratchet teeth of the handcuff strand and allowing release of the handcuff strand when both of the pair of buttons are depressed.
According to a second embodiment, there is provided a handcuff comprising a handcuff strand comprising ratchet teeth, a pair of buttons, each button of the pair of buttons positioned within a respective opposite facing exterior strand of the handcuff, and a spring configured to receive rotational force and cause rotation of a first rotating element. Rotation of the first rotating element rotates a second rotating element, releasing the second rotating element from the ratchet teeth of the handcuff strand and allowing release of the handcuff strand when both of the pair of buttons are depressed.
According to a third embodiment of the present design, there is provided a handcuff comprising a handcuff strand comprising ratchet teeth, a first button positioned within a first double strand element, the first button positioned proximate to and opposite a second button positioned within a second double strand element, and a spring configured to receive rotational force and cause rotation of a first rotating element. Rotation of the first rotating element rotates a second rotating element, releasing the second rotating element from the ratchet teeth of the handcuff strand and allowing release of the handcuff strand when the first button and the second button are depressed.
Various aspects and features of the disclosure are described in further detail below.
The present design is related to enhanced security handcuffs requiring more than a single handed manipulation to open the handcuffs while using a standard handcuff key. In certain instances two or even three hands are required to open the cuffs, typically including one hand that turns a standard handcuff key and at least one other hand that releases mechanical components on the handcuffs. Multiple and simultaneous processes may be necessary to unlock the handcuffs according to the current design.
Millions of people are arrested or detained by law enforcement agencies and related entities each year and are subsequently handcuffed in order to restrain their limbs to prevent escape and/or attack. The use of handcuffs is accepted as an effective restraint system and they are used by every major law enforcement agency in the world. The standard handcuff ratcheting design utilizing a universal handcuff key has been virtually unchanged for more than 100 years and is still in use around the world today. Handcuffs are a critical piece of law enforcement equipment and very few effective alternatives to standard handcuffs exist. Most law enforcement agencies purchase and utilize handcuffs which are similar in design and capability regardless of the manufacturer.
Law enforcement officers are typically trained in one-handed techniques to place handcuffs on a suspect's wrists and a two-handed operation to uncuff a suspect. A standard key is used for almost all handcuffs and is universal in that the same key can be used to open almost all sets of handcuffs regardless of manufacturer. Because handcuff keys are universal and millions exist, they are readily accessible to suspects and inmates restrained by handcuffs, creating a tremendous liability to law enforcement officers. This condition is exemplified in the event those under arrest or being detained are able to obtain or conceal a handcuff key and uncuff themselves. This danger extends to members of the public, and in some cases, prison inmates. A simple design enhancement can make standard handcuffs substantially more effective in their capability to restrain a wearer even if the wearer is in possession of a handcuff key, and such an improvement is the subject of the present design.
The enhanced security handcuffs according to the present design address a need for a more secure, “unpickable” handcuff. Over the years, manufacturers have attempted to improve upon the traditional handcuff design, typically seeking to create a more advanced key and corresponding locking mechanism. This route, however, has been largely unsuccessful.
Although many of the variations herein discuss the use of a standard universal handcuff key, it should be noted the designs incorporated herein also apply to handcuffs and restraints employing specialized, propriety and high security keys and locking mechanisms. Such specialized locking mechanisms may also be utilized to employ the designs described herein.
The present design allows for handcuffs to be applied to a suspect with the use of only one hand; however, one aspect of the present design requires simultaneously employing two hands with opposable digits to unlock and/or open the handcuffs, often while additionally manipulating a handcuff key. This requirement makes it extremely unlikely for an individual who is wearing the handcuffs to unlock and/or open them. This is largely because the wearer of the handcuff has one hand locked in a position where it cannot be used to manipulate that handcuff in any way. As a result, this design, requiring that two free hands act separately and simultaneously to unlock the handcuffs, makes it extremely unlikely an individual will be able to unlock the handcuffs even if he or she is in possession of a handcuff key, shim, or other lock picking device, or employs force or strikes the handcuffs against a hard surface in an attempt to open the handcuffs.
As used herein, various terms are employed and are intended to be used in the broadest sense possible. For example, the present application uses the term “officer” or “law enforcement officer” or otherwise to indicate the individual employing the handcuffs or similar restraints, and as such the term is meant to broadly encompass any individual who may have use for such a device or system, including but not limited to police officers, military personnel, corrections officers, security personnel, or other interested individuals.
The design of the handcuffs may differ from the exact configuration(s) described herein.
With respect to restraints, the term “handcuffs” is intended broadly to mean any type of handcuffs, thumb cuffs, waist chains, leg irons and/or any other type of restraint designed to restrain a person's body part(s) to include but not limited to his or her hands, wrists, fingers, arms, legs, ankles, feet, waist, shoulders, neck or any other body part. These are collectively referred to henceforth as “handcuffs”.
Further, certain designs and capabilities are described herein as being a single variation or capability while others are described as having multiple capabilities. It is understood that the invention is not limited solely to the configurations described but single or multiple configurations may be employed in a single restraint or handcuff respectively, as long as the functionality described is fully or in part incorporated. The foregoing and other concepts disclosed herein are intended to be interpreted broadly and not limit the scope of the present invention.
As used herein, the term “wearer” is synonymous with the term “suspect” or “individual” or any other similar term to convey someone to whom the handcuffs have been applied or a person whom the device is intended to restrain.
In the past, handcuff manufacturers have created handcuffs with different designs to enhance security. The predominant method has been to redesign the locking mechanism to use a more complicated and/or different key. Invariably, each system has been unsuccessful without significant acceptance or use. The requirement to utilize a “standard” universal handcuff key is critical from an operational effectiveness perspective. The use of a universal handcuff key enables peace officers, security officers and correctional officers to unlock handcuffs without having to identify which keys belong to which handcuff. Additionally, officers are thereby only required to carry one handcuff key, as opposed to multiple keys belonging to various disparate restraint systems.
The design described below utilizes a traditional handcuff key, which is universally available and standardized. In certain instances, if desired, the handcuffs of the present design may employ specialized and proprietary key and locking systems to increase their effectiveness. Such handcuffs may also incorporate multiple design features discussed herein.
All drawings, schematics or other visual depictions in these designs encompass a set of handcuffs working in unison to secure one or more appendages of a wearer. In some drawings, only a single unconnected handcuff is depicted. A second handcuff is not depicted in some drawings for clarity and simplicity reasons. Actual designs will normally encompass at least two separate handcuffs connected via one or more of several available methods such as a metal chain, links, roller chain, clasps, hinges, solid bar or any other method. At least one, or in many cases, both of the individual cuffs employ the designs depicted herein.
The rocker arm and button arrangement is illustrated in
Certain solutions are presented in
This alternate design reflected in
Other versions of the various components may be offered, such as a rocker having a different construction, or a double lock spring that appears differently but performs the same function. However, the teachings of the present design, including two facing buttons, an arrangement to enable turning of a key in combination with button pressing to release the cuff, and in certain instances a star wheel component, may be employed to obtain the benefits discussed herein.
Further, while a single cuff is shown in the present drawings, it is understood that such cuffs are typically provided in pairs, and a pair of handcuffs according to the present design may include two handcuffs joined by a chain in accordance with the present disclosure or one such handcuff and a more traditional handcuff joined by a chain.
Thus according to the present design, there are provided buttons that must be depressed simultaneously with the turning of a universal key. The design also includes a rocker arm, in one embodiment having a circular type central component with two peripheral “arms” specially formed therewith. The rocker arm rotationally engages and disengages with the aforementioned buttons. Engagement and disengagement is the consequence of spring loading the buttons in one direction and depressing them in the opposite direction by a user's fingers. This combined action results in the engagement and disengagement of mating flat features on the buttons, stopping or enabling and facilitating rotation of the rocker arm. This depends on whether the buttons are in a closed/locked orientation (extended by the spring) or an open/unlocked orientation (depressed by the user).
The design decreases or eliminates the use of a traditional double lock bar, thus reducing or eliminating the risk associated with an inertia striking action that can disengage a double lock bar. Previous designs have used a spring-loaded pawl to engage mating ratchet teeth to a pivoting strand's ratchet teeth. Should these mating teeth wear over time, it is possible that the cuff or cuffs can be rendered inoperable. The present design employs a pawl that exerts a pivoting force that increases as the strand is pulled upon in the direction of release. This action is the result of the approximate location of the pivot of the binding pawl relative to the pivot location and rotational direction of the single strand.
The present design also utilizes an anti-pick spring device that retains the rocker arm in position and prevents picking from the keyhole when the handcuff is in a locked or double locked orientation. The spring, called a double lock spring, is a “U” shaped spring with angled lead in tangs that allow a universal handcuff key to spread the “U” shape of the spring. At the ends of each leg of the “U” are corresponding “L” shaped catching features that engage the end of the rocker arm, preventing the rocker arm from rotating into an unlocked position. As the user turns the universal handcuff key clockwise, the angled lead in tangs spread, releasing the “L” shaped catches, thus allowing the rocker arm to rotate. This consequently engages the opposite end of the rocker arm to the binding pawl and releases the single strand. The action of spreading the anti-pick spring in both an upward and downward direction and simultaneously slot formed in the rotate the rocker arm while using a picking device makes it difficult or impossible to pick the lock from the keyhole.
As a further alternative, the present design may employ other countermeasures inhibiting picking or defeating.
To be clear, use of the “user” in this document is intended broadly and can mean the wearer or the person releasing the cuff from the wearer. In some instances, one individual, including the wearer, may have his or her hand on one or both buttons while a second individual is turning a key in the cuff to release the cuff. Hence any recitation of “user” “wearer” “suspect” “person” “individual” or other entity operating the current design is not intended to be limiting.
The present design also employs a star wheel shaped piece in one embodiment that rotates on shafts inserted into holes of the double strand pieces of the handcuff. The star wheel's teeth mesh with the ratchet teeth of the single strand. The meshing of these two mating teeth prevent a pick from passing through, in between them. Such a device is optional and may or may not be included in an individual cuff in accordance with the present design.
The rocker arm includes an extended bar feature. At the end opposite where the key engages the rocker arm is an extended bar feature that engages the binding pawl. This extended arm serves two purposes—first, to unlock the handcuff by engaging with the binding pawl. Unlocking is the result of the universal handcuff key being turned clockwise when inserted into the keyhole. This action rotates the rocker arm in a counterclockwise direction such that the extended bar feature engages a protrusion of the binding pawl, rotating the binding pawl in a direction that disengages its ratcheting teeth from the ratcheting teeth of the single strand provided. A second purpose of the extended bar of the rocker arm is used to double lock the handcuff after the handcuff has been attached to a suspect's wrist. The universal key has a protrusion located on its handle end. This protrusion is used for double locking. The key is inserted into a slot located on each face of the double strand cuff assembly. After insertion the key is pushed in the direction of the wrist, rotating the rocker arm clockwise. The extended bar feature of the rocker arm then rotates into a notch of the binding pawl, preventing the binding pawl from rotating. This engagement also serves to keep the single strand from ratcheting further against the wrist that, in the past, has caused injury to the wrist.
Thus according to one embodiment, there is provided a handcuff comprising a handcuff strand comprising ratchet teeth, a pair of buttons on opposing sides of the handcuff, and a spring configured to receive rotational force and cause rotation of a first rotating element. Rotation of the first rotating element rotates a second rotating element, releasing the second rotating element from the ratchet teeth of the handcuff strand and allowing release of the handcuff strand when both of the pair of buttons are depressed.
According to a second embodiment, there is provided a handcuff comprising a handcuff strand comprising ratchet teeth, a pair of buttons, each button of the pair of buttons positioned within a respective opposite facing exterior strand of the handcuff, and a spring configured to receive rotational force and cause rotation of a first rotating element. Rotation of the first rotating element rotates a second rotating element, releasing the second rotating element from the ratchet teeth of the handcuff strand and allowing release of the handcuff strand when both of the pair of buttons are depressed.
According to a third embodiment of the present design, there is provided a handcuff comprising a handcuff strand comprising ratchet teeth, a first button positioned within a first double strand element, the first button positioned proximate to and opposite a second button positioned within a second double strand element, and a spring configured to receive rotational force and cause rotation of a first rotating element. Rotation of the first rotating element rotates a second rotating element, releasing the second rotating element from the ratchet teeth of the handcuff strand and allowing release of the handcuff strand when the first button and the second button are depressed.
The previous description of the disclosure is provided to enable any person skilled in the art to make or use the disclosure. Various modifications to the disclosure will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other variations without departing from the scope of the disclosure. Thus, the disclosure is not intended to be limited to the examples and designs described herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.
The present application is a continuation of co-pending U.S. patent application Ser. No. 16/262,735, entitled “Enhanced Handcuff Apparatus,” inventor Ivanhoe Chaput, filed Jan. 30, 2019, which claims priority based on U.S. Provisional Patent Application Ser. No. 62/768,366, filed Nov. 16, 2018, inventor Ivanhoe Chaput, entitled “Enhanced Handcuff Apparatus,” the entirety of both of which are incorporated herein by reference.
Number | Date | Country | |
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62768366 | Nov 2018 | US |
Number | Date | Country | |
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Parent | 16262735 | Jan 2019 | US |
Child | 16709839 | US |