The foregoing objects are among those attained by the invention, which provides, in some aspects, a coupler for inline connection of two bodies where one of the bodies provides linear motion to the other. In a particular embodiment, the coupler joins a compression module of a mechanical CPR device to a patient interface of that device.
Further aspects of the invention provide a coupler, e.g., of the type described above comprising a first adapter linearly engaging a second adapter in a capture B. The first adapter defines a capture C for temporarily securing a first compatible body, and the second adapter defines a connector for securing a second compatible body. The capture B and the connector are oriented one to the other such that linear movement of the first compatible body translates into linear movement of the second compatible body. The capture B releases the secured compatible body upon pressing together of the first and second adapter.
In related aspects, the invention provides a coupler, e.g., as described above, wherein the capture B has a spring latch mounted in the first adapter and a catch in the second adapter, the catch being a surface of the second adapter that is engaged by the spring latch.
Further related aspects of the invention provide a coupler, e.g., as described above, wherein the capture C has a spring latch and a catch that is a surface of the second adapter, whereby the first compatible body is trapped between the spring latch and the surface.
Yet still further related aspects of the invention provide a coupler, e.g., as described above, wherein the first adapter has a capture A. The capture A comprises a spring latch for temporarily securing the coupler to a third compatible body while the coupler is securing the first compatible body. The third body has a surface that when it engages the spring latch the coupler is released from the third compatible body.
Still yet further related aspects of the invention provide a coupler, e.g., as described above, wherein the connector is a rim, and wherein the second body has a suitably dimensioned groove to accept the rim.
Further related aspects of the invention provide a coupler, e.g., as described above, wherein the first compatible body has a cylindrical portion with a distal end to be inserted into a bore defined by the first adapter.
In a further related aspect, the invention provides a coupler, e.g., as described above, wherein the first compatible body has a rim on the distal end for engaging the coupler C.
In still a further related aspect, the invention provides a coupler, e.g., as described above, wherein the capture B only releases the second compatible body upon relative motion between the first and second adapters.
Yet further related aspects of the invention provide a coupler, e.g., as described above, wherein the secured compatible bodies each have a centerline, and the bodies when secured have a common centerline.
Other related aspects of the invention provide a coupler, e.g., as described above, wherein the first compatible body is a distal end of a ram of a mechanical CPR device.
Yet still other related aspects of the invention provide a coupler, e.g., as described above, wherein the second compatible body is a patient interface device for a mechanical CPR device having a groove to receive the connector.
Still yet other related aspects of the invention provide a coupler, e.g., as described above, wherein the patient interface device includes a structure designed to permit temporary attachment of the patient interface device to a patient's chest.
Yet still other related aspects of the invention provide a coupler, e.g., as described above, wherein the third compatible device is a support assembly of a mechanical CPR device.
Further related aspects of the invention provide a coupler, e.g., as described above, wherein the first and second adapter are round.
In other aspects, the invention provides a mechanical CPR device comprising a support assembly having a compression module and a backboard coupling to the support assembly to define an area for placement of a patient's torso between the compression module and the backboard. The compression module has a ram and a patient interface device, the patient interface device being attached to the ram by a coupler. The coupler includes a first adapter linearly engaging a second adapter in a capture B, the first adapter defining a capture C for temporarily securing a first compatible body and the second adapter defining a connector for securing a second compatible body. The capture B and the connector are oriented one to the other such that linear movement of the first compatible body translates into linear movement of the second compatible body, and the capture B releases the secured compatible body upon pressing together the first and second adapter.
Related aspects of the invention provide a coupler, e.g., as described above, wherein the compression module is only temporarily secured in the support assembly and is only removable therefrom by removing the coupler from the ram.
Further aspects of the invention provide a method for coupling a patient interface device to a mechanical CPR device. The method includes the steps of providing a mechanical CPR device having a reciprocating body; providing a coupler that is compatible to engage and be temporarily secured to the reciprocating body, wherein the coupler has two adapter assemblies and is disengaged by pressing (or squeezing) the two adapters together; attaching a patient interface device to the coupler; and attaching the coupler to the reciprocating body.
Related aspects of the invention provide a method, e.g., as described above, further including the step of securing the coupler to the mechanical CPR device prior to the attachment to the reciprocating device.
Further related aspects of the invention provide a method, e.g., as described above, further including the step of securing the coupler to the mechanical CPR device prior to attachment to the reciprocating device in a position such that the reciprocating device is capable of disconnecting the reciprocating device from the mechanical CPR device.
Yet still further related aspects of the invention provide a method, e.g., as described above, further including the step of decoupling the coupler from the mechanical CPR device by installing the reciprocating device in the mechanical CPR device.
Further aspects of the invention are evident in the description that follows, the drawings and the claims.
A more complete understanding of the invention may be attained by reference to the drawings, in which:
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Continuing with
Focusing on the first level 110, the first level's exterior upper surface 136 has several depressions 130. The depressions are shaped and sized to interact with the thumbs of a person (not shown). The use of these depressions is discussed below.
Focusing on the first level 110 and the second level 112, there is a connecting exterior middle wall 138. The exterior middle wall has a series of openings for a series of Latches A 116. The Latches A are a portion of a Captures A (referred to by reference number 114) which further includes a Catches A 118. The Captures A joins the upper body 104 to a to be determined compatible body. The Captures A is further discussed below in an illustrative application having an illustrative compatible body.
As illustrated herein, a “capture” is something that secures one thing to another. In this illustrative embodiment a capture includes a hinged latch that interacts with a surface to secure a compatible body. In some cases, this interaction defines a space, or void into which a compatible body is effectively trapped, and in other cases the latch may interact with the other body, such as by snapping into a surface of a void in the other body.
In this embodiment, the Latches A 116 of the first adapter 104 are hinge mounted within the exterior lower surface 136 and shaped to place the appendage A above the exterior lower surface. Thus, in operation, a compatible body upon contacting the Latches A causes the Latches A to deflect inward and upon passing by the appendage A the Latches A returns to is original position trapping the compatible body between the appendage and the Catches A.
This Captures A 114 further allows for decoupling of a compatible body from the coupler 100 by depressing release A 120. Thus, the Captures A can be used when it is desirable to have a non-destructive means of releasing the captured compatible body from the coupler 100. More specifically, releasing the captured compatible body is accomplished by pressing on the Release A, whereby the Latches A 116 will deflect inward causing the appendage A 122 to relocate and release the captured compatible body.
Focusing on the underside of the first adapter 104,
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As previously described, the first adapter 104 is mated to the second adapter 108 by Captures B. Referring to
Captures B may be designed to allow a compatible body captured by Captures C 204 to be released. Referring again to
Illustrative Usage of the Coupler
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In this mechanical CPR device 310, the compression module 316, which is well known in the art, contains the necessary electronic, computer programming and power source to cause the patient interface to reciprocate thereby providing CPR to a patient to which the patient interface is affixed. The basic components of this type of CPR device are a compression module, support assembly 314 and backboard 318. A typical example of such a CPR device is Defibtech's ARM.
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Primary components of the compression module 316 relevant to the invention are a ram 322 having a distal end flange 326, inside an inner sleeve 330 which is inside an outer sleeve 330. The compression module is mounted within a bore 324 defined by the support assembly 314 and held in the bore by a coupling system having a cooperating Latches 332 and Catches 334. In this exemplary usage, the coupling is made by having the compression module inserted into the bore such that for operation a 90-degree rotation is required to fully engage the compression module in the support assembly. During coupling, the rotation of the compression module 90 degrees causes the compression module to advance and lock in the bore 324.
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It should be noted that the distal end flange 326 when trapped in Catches C 208 is dimensioned to prevent linear movement of the second adapter 108 relative to the first adapter 104 by pushing upward on the second adapter, where the position of the first adapter is not fixed. This connection, however, can be released, which is discussed below.
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While certain example or illustrative examples have been described, these examples have been presented by way of example only and are not intended to limit the scope of the inventions disclosed herein. Indeed, the novel methods and systems described herein may be embodied in a variety of other forms. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of certain of the inventions disclosed herein.
This application claims the benefit of priority of U.S. Patent Application Ser. No. 63/378,495, entitled Coupling Apparatus, filed Oct. 5, 2022, the teachings of which are incorporated herein by reference. Cardiopulmonary Resuscitation (CPR) is a well-known, first-aid treatment ideally performed on a patient suffering cardiac arrest. CPR is an external heart massage technique that manually preserves blood circulation through a patient's body in an attempt to maintain the body's organs, primarily the brain, until a normal heart rhythm, or blood flow, can be restored. Performing manual CPR (i.e., CPR compressions given by a person) is strenuous, even using devices that provide a mechanical advantage. Proper CPR requires about 100, 5-cm-deep compressions of the chest per minute, each compression potentially requiring a force upwards of 550 N. Therefore, maintaining high-quality, manual CPR for an extended period, even more than several minutes, can be exhausting. Additionally, a CPR provider must maintain proximity to the patient. Maintaining proximity can be challenging to impossible when the patient on whom the CPR is being performed is being moved, whether being carried on a backboard (e.g., through doorways, down halls or on stairs) or being transported in a vehicle. Autonomous mechanical CPR (AMCPR) devices, which are well known in the art, can overcome many of the issues associated with providing manual CPR. These AMCPR devices can be associated with a patient and once started do not require human intervention, or even necessitate human proximity, and will continue CPR until depletion of their power source. AMCPR devices generally comprise an upper portion, sometimes referred to as a support assembly that includes a compression unit (i.e., a device having a control system, power source, and extendable ram) for compressing a patient's chest. The support assembly engages a lower portion, sometimes referred to as a backboard. The support assembly and backboard thereby defining a space into which a patient's torso may be positioned. Some support assemblies are self-supporting, but that need not be the case. Additionally, the space may be fully surrounding the patient's chest or partially surround it. The compression unit is fixed, permanently or temporarily, in the support assembly in such a manner as to interact with a patient's chest proximate the sternum. Where the compression unit has an extendable, reciprocating ram, the ram is ideally positioned with a line of applied compressive force perpendicular to the chest. The protocol for providing mechanical CPR has evolved. Early on, mechanical CPR was performed by AMCPR devices compressing the chest from the chest's natural position and then letting the chest naturally return to a position, hopefully proximate the natural position, and then compressing again. It was then determined that it might be desirable that instead of allowing the chest to naturally return to its natural position, it might be beneficial to pull the chest back to a position proximate but at or below the chest's natural position. Then, it was determined there might be beneficial to not only pull the chest back to its natural position but pulling it above the chest's natural position. The desire to pull up on the chest required that the AMCPR device's compression unit be affixed to a patient's chest. Formerly, the patient interface of the compression module was a pad like structure that merely distributed the force of the CPR over a suitable surface area above the patient's sternum and was not connected to the chest. The need to pull up on the chest required a patient interface that would interact with the patient's chest, i.e., attach to, and withstand the tensile force needed to actually pull the chest upward. As a result of this “pulling” requirement, the patient interface became ever larger to assure the strength of the necessary connection to the chest. For AMCPR devices with removeable compression modules, the ever-larger patient interface devices proved problematic. More precisely, for AMCPR devices with removable compression modules, the compression module mounts above, and the compression mechanism passes through a bore in the support assembly. It was either not feasible and/or desirable to increase the bore size to accommodate the ever-larger patient interface devices. Therefore, a coupler had to be made to affix it with patient interface device with the compression module but allow the patient interface device to be decoupled from the compression module to facilitate the removal of the compression module. The coupler of the present invention facilitates the coupling and uncoupling of the patient interface device from the compression module. In situations where it is desirable to store the coupler in a deployable position on the AMCPR device, an optional capture feature may be added to the coupler to temporarily connect it to the AMCPR. These and other aspects and advantages of the invention will become apparent from the following detailed description and the accompanying drawings that illustrate by way of example the features of the invention.
Number | Date | Country | |
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63378495 | Oct 2022 | US |