Often mobility impaired patients must be transferred to and from hospital beds, examination tables and operating tables. Traditional devices, including wheeled gurneys and stretchers, often require the use of several personnel to affect transfer, which can require pulling personnel from other jobs or functions, if only momentarily, to assist. Transfers using these devices can lead be very evasive to the patient and the staff. These devices can result in additional injury and stress to both the patient and the staff if the transfer process is not meticulously followed by all involved. Even if transfers are affected according to procedure, they still allow and even cause significant body movement of the patient that can result in patient stress, pain, injury, and discomfort. Usually, if the patient is cooperative and not injured or disabled, it is a simple matter for the individual to slide over to the gurney with the assistance of a nurse, but if the patient is unconscious or has a disability or an injury (e.g., a broken bone) that might be worsened by movement, then great care must be taken in transferring the patient from a bed to a gurney. This problem is exacerbated when the patient is above average weight.
One solution to the disabled or unconscious patient transfer problem is to slide a tray or sheet under the patient and then, after the patient is resting atop it, pull the tray or sheet off the bed and onto the gurney. A rigid tray can usually be forcibly slid between the patient and the bed, and a sheet can be incrementally pushed under the person by first rocking him away from the gurney and then rocking back toward the gurney as the sheet is drawn under. This approach can still be difficult if the patient is uncooperative (i.e., unconscious), and can further be very uncomfortable even if the patient is cooperative, due to the frictional engagement of the tray with the body or the lack of firm support by the sheet.
Automated transfer devices have been proposed that reduce the number of workers required for a transfer and make the transfers safer and less traumatic for the patient. However, devices proposed to date have all suffered from one or more drawbacks and have not seen widespread implementation.
Embodiments of invention comprise a patient transfer device and an associated method of transferring a patient using the device. The device is used anytime a patient needs to be moved or transferred out of bed especially in those circumstances wherein the patient is in any way incapacitated and is unable to move or assist in the transfer. The device transfers the patient laterally from a longitudinal side of the bed onto the device. The transfer can be accomplished with minimal medical staff interaction and as such significantly and substantially reducing the risk or injury and harm not only for the patient but also the staff.
Generally, the transfer device has a C-shaped frame comprising a wheeled base, lifting columns rising upwardly from base and terminating in framework for supporting a conveyor unit assembly that is configured to both transfer a patient and support the patient when he/she has been transferred there on. The leg portion is typically height adjustable to properly align to any height bed or surface provided there is clearance for the wheeled base. Safety railings are provided on all sides of the frame to protect the patient from rolling off when being transported but the front safety rail is configured to be moved from the loading side of the device to facilitate the transfer operation. Front railing (not shown) rotates from front while patient is being transported. When patient is being loaded the railing pivots back and tucks alongside the non-one of the left and right sides of the device until patent is loaded on the device.
The conveyor unit assembly comprises separate upper and lower conveyor units that in operation rotate in an opposite direction relative to the other but at substantially the same speed. In the assembly, the upper and lower units are joined together to facilitate cooperative operation. The lower conveyor is configured to pull or push the device onto or off of an elevated bed or similar elevated top surface while the base is drawn under the bed or surface. The upper conveyor unit is configured to move the patient to and from the bed or other top surface.
In the loading and unloading configuration, the conveyor assembly unit is canted at a slight approach angle off of horizontal to better facilitate conveying the patient on or off the device. This loading angle also allows for the lower conveyor to drive parallel to the transfer surface. Embodiments of the transfer device include an option to pivot to a fully horizontal position during transfer typically after the patient is completely loaded thereon.
Embodiments of the patient transfer device are designed to easily permit a full wash down when necessary for sanitary reasons as is desirable in a hospital setting. The device does not having exposed recesses and locations where water and cleaning solution could pool and stagnate for long periods of time. In some embodiments to access to all surfaces and areas of the device, the conveyor bases can be pivoted into a wash down configuration that loosens the conveyor belts and allow easier access to the backsides of the belt and the surfaces there beneath.
At least some embodiments of the device are powered by deep cycle rechargeable batteries while other variations can be AC powered or have the capability to use both AC and battery power. Control of the electrical systems is typically provided by way of either or both a handheld interface pendant control and one or more touch screen displays.
The terms and phrases as indicated in quotation marks (“ ”) in this section are intended to have the meaning ascribed to them in this Terminology section applied to them throughout this document, including in the claims, unless clearly indicated otherwise in context. Further, as applicable, the stated definitions are to apply, regardless of the word or phrase's case, to the singular and plural variations of the defined word or phrase.
The term “or” as used in this specification and the appended claims is not meant to be exclusive; rather the term is inclusive, meaning either or both.
References in the specification to “one embodiment”, “an embodiment”, “another embodiment, “a preferred embodiment”, “an alternative embodiment”, “one variation”, “a variation” and similar phrases mean that a particular feature, structure, or characteristic described in connection with the embodiment or variation, is included in at least an embodiment or variation of the invention. The phrase “in one embodiment”, “in one variation” or similar phrases, as used in various places in the specification, are not necessarily meant to refer to the same embodiment or the same variation.
The term “couple” or “coupled” as used in this specification and appended claims refers to an indirect or direct physical connection between the identified elements, components, or objects. Often the manner of the coupling will be related specifically to the manner in which the two coupled elements interact.
The term “directly coupled” or “coupled directly,” as used in this specification and appended claims, refers to a physical connection between identified elements, components, or objects, in which no other element, component, or object resides between those identified as being directly coupled.
The term “approximately,” as used in this specification and appended claims, refers to plus or minus 10% of the value given.
The term “about,” as used in this specification and appended claims, refers to plus or minus 20% of the value given.
The terms “generally” and “substantially,” as used in this specification and appended claims, mean mostly, or for the most part.
The terms “removable”, “removably coupled”, “removably installed,” “readily removable”, “readily detachable”, “detachably coupled”, “separable,” “separably coupled,” and similar terms, as used in this specification and appended claims, refer to structures that can be uncoupled, detached, uninstalled, or removed from an adjoining structure with relative ease (i.e., non-destructively, and without a complicated or time-consuming process), and that can also be readily reinstalled, reattached, or coupled to the previously adjoining structure.
Directional or relational terms such as “top,” bottom,” “front,” “back,” “above,” “beneath,” “upper,” “lower” and “below,” as used in this specification and appended claims, refer to relative positions of identified elements, components, or objects, where the components or objects are oriented in an upright position as normally installed or used.
The term “arcuate” as used herein refers to a curved surface or line. The curved surface or line need not comprise an arc or portion of circle, but may also comprise a portion of an oval or other shape comprising a curved surface. Accordingly, the terms “radius” and “effective radius” refer to the radius a circle that most closely matches with the referenced arcuate surface or line.
The phrase “integrally formed” or the term “integral” as used herein refers to something that is a portion of the whole. For instance, integrally formed portions are portions of the whole that are formed from the same base material and at essentially the same time as the whole.
The term “patient” as used herein refers to a person on which the patient transfer device can be used to move the person from one location to another. The term is not to be interpreted as limiting any description or claim to use only with people who are patients of a medical institution or medical practitioner.
The term “conveyor” or the phrase “conveyor unit” refers to a system using an endless belt (including endless tracks) rotated around opposing and spaced apart ends wherein the ends typically, but not necessarily, comprise rollers.
An embodiment of a fully assembled patient transfer device 100 is illustrated in
Generally, the frame unit 102 comprises a C-shape having a plurality of substantially vertical lifting columns 108A-C that that span between a wheeled base 110 and an upper frame portion 112 adapted to receive the conveyor unit assembly 104. The C-shape permits the wheeled base to be drawn under the bed or other surface from which a patient is being transferred there by contributing to the stability of the device as a person is loaded on or off of it. To further enhance stability end beams 114 of the wheeled base 110 can extend outwardly of the remainder of the base as best illustrated in
The conveyor unit assembly 104 comprises upper and lower conveyor units 120 & 122 that are mechanically joined together at each end by mounting plates 124 and associated fasteners. The mounting plates also include pivots shafts 126 extending outwardly there from for receipt into the bearing mounts 116 to pivotally couple the conveyor unit assembly to the upper frame portion 112. Each conveyor unit includes separate belts and drive motors. The motors are synced through the controllers of the electrical system to rotate the conveyors at the same linear speed albeit in opposite directions.
The electrical/control system 128 includes but is not limited to the linear actuators (not shown) located in one or more of the vertical lifting columns, the drive motors 130 & 132 in the upper and lower conveyor units 120 & 122, the touch screen display 106, linear actuators 134 coupled to the frame and the conveyor unit assembly 104 for effecting the tilt thereof, actuator motors 136 for the extension and retraction of the wheel base end beams 114, controllers and associated logic for controlling the operation of the various components, one or more batteries, and circuitry for recharging the batteries along with all necessary wires and electrical traces operatively connecting the electrical components.
The wheeled base 110 comprises a generally C-shaped framework forming a platform 138 along the rear thereof. The three vertical lifting columns 108A-C rest upon and are mounted to the top of the platform. Mounted on the underside of the platform on opposite ends there of are wheeled casters 140. In some variations of the patient transfer device, a drive wheel 142 with an associated motor may be mounted under the center of the platform to facilitate powered movement of the device whether during patient transfer to and from the device as well as the propulsion of the device from one location to another (see
From each respective end of the rear platform, the end beams 114 extend forwardly to form the C-shaped wheeled base. The end beam is slidably coupled to the remainder of the wheeled base 110 by way of sliders 144, which through the use of an associated linear actuator can be moved forwardly into an extended position relative to the platform about 6″-12″ from a retracted position. A wheeled caster 140 is mounted to the underside of each end beam to provide support for the frame unit and the patient transfer device.
Each of the vertical lifting columns 108A-C comprises three nested tubular members that together can telescope to increase in length as is best shown in
The upper frame portion 112 comprises a girder beam 146 that is mounted to the topside of the vertical lifting columns by way of a mounting plate 148. The girder beam extends outwardly from the lifting columns ultimately having a length greater than the length of the wheeled base and most typically at least a little bit longer than the length of a typical hospital bed mattress. From each of the left and right ends of the girder beam, an upper leg 150 extends orthogonally, substantially horizontally and forwardly. Also from each end of the girder beam, a tilt actuator beam 152 extends downwardly with the tilt actuator beam terminating at a location vertically at least several inches above the bottom of the wheeled castors or an underlying floor when the vertical lifting columns are fully retracted.
The girder beam 146 typically comprises a pair of spaced horizontally-extending square or rectangular tubing that is joined by vertical tubes spaced along the length thereof. The girder beam also acts as a safety railing when a patient is resident on the device substantially preventing the patient from rolling or sliding off the backside of the surface of the upper conveyor unit. As shown in the various Figs, a touch screen control interface 106 can be mounted to the top side of the girder beam.
Each horizontal upper leg 150 extends a length comfortably greater than the width of a patient that might be transported on the device. The safety railing 118 is typically mounted to the topside of each leg, and the bearing mount 116 is secured to the bottom side about midway along its length. The bearing mount is configured to pivotally receive a corresponding pivot shaft 126 of the conveyor unit assembly 104.
Each tilt actuator beam 152 is configured to pivotally receive at its bottom end a bottom end of a linear actuator 134 of which the actuator's top end is pivotally coupled to the conveyor unit assembly 104 as seen in
In some variations of the patient transfer device 100, one or more drive wheels are provided to assist in or independently propel the device. As shown in
The frame unit 112 can be comprised of any suitable material or a combination of suitable materials, although typically the frame unit is comprised primarily of a metal material such as steel or aluminum. Further, the exact configuration of the frame unit can change substantially from what is depicted herein while maintaining a C-shape as is best shown in the side view illustration of
The conveyor unit assembly 104 is illustrated in
Each conveyor unit 120 & 122 comprises a truss frame 154A&B & 156A&B over which guide plates are secured 158A&B & 160A&B. The truss frames are tapered being thickest at the rear and thinnest at the front end. Each truss frame comprises front portions 154A & 156A and rear portions 154B & 156B that are pivotally connected by way of a hinge 162 & 164 that runs the entire length of the unit permitting each unit to be moved into a cleaning configuration as will be described supra. Front guide plates 158A & 160A are attached to the front truss portion 154A & 156A, and rear guide plates 158B & 160B are attached to the rear truss portion 154B & 156B. The guide plates provide surfaces over which the conveyor belts 166 can easily slide. The plates are located on the top side of the upper conveyor unit 120 and on the bottom side of the lower conveyor unit. At the thinner front edge of each conveyor unit one or more rollers 168 & 170 are provided around which the conveyor belt transitions from one of the top and bottom surfaces to the other. At the rear edge a motor-driven large roller 172 & 174 is provided. The electric drive motor 130 & 132 is mounted forward and adjacent to the large roller and operatively coupled with it by way of a drive belt 176 & 178.
With reference to
Both conveyor units 120 & 122 are of substantially similar lengths permitting them to be easily joined together at the ends by the side mounting plates 124. However, the lower conveyor unit has a shorter width than the upper conveyor unit such that when the two are joined together. This configuration reflects the fact that a patient is going to be laying in several inches at the minimum from the edge of a bed.
The hinged truss frames 154 & 156 of the upper and lower conveyor units 120 & 122 are configured to permit each conveyor unit and collectively the conveyor unit assembly 104 to be placed in a cleaning configuration as shown in
While in the cleaning configuration the tension of the conveyor belts can be adjusted with relative ease. Referring to
Additionally, the pivotal frame trusses 154 & 156 also facilitate in the periodic removal and replacement of the belts 166 when the conveyor unit assembly is removed from the frame unit 112 and the upper and lower conveyor units 120 & 122 are separated as the conveyor belts can slide easily off and on the respective unit when the respective portions of each unit are put into the tilted orientation.
Referencing the side view of the conveyor unit assembly 104 as shown in
The electric control module 502 or system controller comprising suitable micro circuitry serves to control the operation of all electrical components receiving and processing data and electronic signals from various sensors and components and accordingly adjusting the operating parameters of the device.
Most operations of the patient transfer device are initiated as a result of direction received by the controller 502 from a user interface, such as the an operator touch screen panel 106 or a wired or wireless handheld remote pendant 504. Some of the functions initiated from the user interfaces as detailed in block 506 include: the vertical height adjustment of the frame unit; the changing of the angle of the conveyor unit assembly between the loading and transport configurations; the loading and unloading speeds of the conveyor units; the rotation of the conveyor unit assembly to an angle to facilitate placing the conveyor units into their cleaning configuration; and a stop button. Also, in some variations, the user interface will be configured to control the speed and operation of the optional driven wheel 142. In addition to the normal operational functions each of the user interface devices includes an emergency stop function 508. Additional emergency stop buttons 510 may also be placed in strategic location on and around the device.
Some of the components controlled by the controller include: linear actuator motors 130 & 132 that drive the upper and lower conveyor units as indicated in block 516; one or more linear actuator motors 134 that tilt or pivot the conveyor assembly unit between its various positions as indicated in blocks 516A&B; one or more linear actuator motors 519 in the lifting columns for adjusting the height of the conveyor unit assembly as indicated in blocks 518A&B; and one or more optional motors 521 & 522 for driving the optional drive wheel and turning the drive wheel to control the direction of the patient transfer device as indicated in blocks 520 & 522. The end beam is extended or retracted to change the device's wheel base by way of linear actuators 136 as shown in block 531A&B.
To assist the controller in accomplishing it various functions, various sensors are provided as are indicated in block 524. One or more sensors are used to determine the pivot angle or orientation of the conveyor assembly unit. One or more sensors are utilized to determine the height of the lifting columns. One or more sensors are also provided to assess the position of the patient on the device to ensure he/she is properly centered thereon. These sensors can also be configured to stop the rotation of the upper and lower conveyors once they have detected the patient is fully received on the device. Finally, a sensor can be provided to determine whether the front sensor gate is in place and properly secured. As can be appreciated the controller may prevent the operator from carrying out certain operations depending on readings from the various sensors. For instance, if the patient is not properly centered on the device or the safety gate is not closed, the controller may not allow the activation of the drive wheel (if the device is so equipped).
Typically, the electrical and control system is powered by a deep cycle battery 526. In some variations that device will only work using battery power and will not function if the residual charge in the battery is below a certain minimum level. Other variations permit AC operation or battery operation. Yet other variations allow only certain functions to operate while using AC power. Typically, the device is configured to prevent the transfer of a patient using AC power or while the device is plugged into a wall outlet. Regardless of the specific variation, a battery charger 528 is typically provided as part of the device and can be housed along with the battery within a provided container that is usually located on the frame unit wheeled base 110 or within one of the hollow lifting columns 108. A small backup battery 530 may also be provided that can continue to power the controller 502 and the user interface even if the primary battery becomes fully discharged. In other variations, a larger backup battery is provided that has sufficient charge to accomplish a small number (1-3) transfers in emergency circumstances as a failsafe if the primary battery becomes fully discharged or otherwise fails.
As shown in block 602, the device is aligned with the hospital bed or other surface on which a patient is lying. The conveyor unit assembly 104 is placed in its loading configuration with the top surface of the upper conveyor angled, and the height of the device is adjusted so the bottom surface of the conveyor unit assembly is essentially the same as the height of the top surface of the bed.
Referring to block 604, the device is positioned next to the bed with the bottom surface of the conveyor unit assembly 104 resting on the top surface of the bed and the front edge of the upper conveyor 120 located close to the side of the patient. As necessary the operator can fine tune the height of the device relative to the bed using the touch screen 106 or pendant user interface. Further, each end beam 114 of the base is extended outwardly by way of the associated linear actuator motors.
As shown in blocks 606-610, the upper and lower conveyor units 120 & 122 are activated so that the belts 166 advance at the same speed as each other but in opposite directions. As shown in the pictures, the upper conveyor belt moves in a clockwise direction and the lower conveyor belt moves in a counterclockwise direction. As the patient is pulled up onto the conveyor, the end beams of the wheeled base 114 are pulled under the bed.
With reference to block 612, once the patient has been fully received onto the conveyor, the operator can pull the device away from the bed and retract the end beams of the wheeled base 110. Finally, as shown in block 614, before wheeling the patient to his/her destination, the operator moves the conveyor unit assembly into the transport configuration wherein the top surface of the upper conveyor 120 is put into a substantially horizontal orientation.
Unloading the patient from the patient transfer device entails performing similar steps and operations but in reverse.
The various embodiments and variations thereof, illustrated in the accompanying Figures and/or described above, are merely exemplary and are not meant to limit the scope of the invention. It is to be appreciated that numerous other variations of the invention have been contemplated, as would be obvious to one of ordinary skill in the art, given the benefit of this disclosure. All variations of the invention that read upon appended claims are intended and contemplated to be within the scope of the invention.
This application is a continuation of U.S. patent application Ser. No. 14/915,792 filed on Mar. 1, 2016 to which priority is claimed. No new matter has been added hereto. U.S. patent application Ser. No. 14/915,792 is a national stage entry of PCT Patent Application No. PCT/US15/53984 filed on Oct. 5, 2015 of which priority was claimed. PCT Patent Application No. PCT/US 15/53984 claimed priority and incorporated fully by reference U.S. Provisional Patent Application No. 62/059/483 filed on Oct. 3, 2014. All related applications referenced above are entitled Patient Transfer Device and have at least one common inventor with the present application.
Number | Date | Country | |
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62059483 | Oct 2014 | US |
Number | Date | Country | |
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Parent | 14915792 | Mar 2016 | US |
Child | 15363805 | US |