The present invention is generally directed to a medical assist device for assisting in the transfer of an infirmed patient from a bed to a chair or chair to a wheelchair or back to a bed or from a wheelchair to a toilet or bathtub. A number of patient or invalid transfer apparati have been disclosed in the prior art, including those disclosed in the following U.S. Pat. Nos. 2,757,388; 2,975,435; 3,911,507; 5,054,137 and 5,079,789, the disclosures of which are incorporated herewith by reference. Typically, the prior art devices utilized a rotatable platform upon which the patient could stand and a support handle which the patient could grip. It is believed that the prior art devices have not found widespread acceptance for one reason or another.
Accordingly, it is an object of the present invention to provide a new, easily usable apparatus for rotationally transferring a patient from one support such as a bed, chair or wheelchair to another of such supports.
It is a further object of the present invention to provide a motor driven apparatus for transferring a patient which, for the very infirmed, cannot be activated by the patient but only by an attendant, preferably through use of a controller which is remote from the patient support platform. For patients who are less infirmed, the medical assist device could be equipped with controls which the patient could operate while standing thereon.
Other objects and advantages of the present invention will become readily apparent to those skilled in the art upon a review of the detailed description of the preferred embodiment and the accompanying drawings.
Under the present invention there is provided a medical assist device having a motor powered rotatable platform upon which a patient may stand while being rotated from one support such as a bed to another support such as a chair or wheelchair. Steadying members for gripping by the patient extend upwardly from the rotatable platform to provide auxiliary supporting means for the patient as he/she is rotated from a position of alignment with one support to a position of alignment with a second support. Under one embodiment, the rotatable platform is power driven through the use of a twin disk mechanism in which a first disk, rotated directly by a motor, engages and rotates a rotatable disk associated with and rotatable with the platform upon which the patient is standing. Means are provided to urge the outer peripheral edge of the rotatable platform into tight frictional engagement with the circumferential edge of the motor driven first disk as that portion of the rotatable platform is displaced downwardly by the weight of a patient standing thereon.
Under other embodiments, the rotatable platform may be powered by various types of gears or by belts and pulleys. The assist device is waterproof and readily cleanable with water or other liquids without damaging the motor or other operating mechanism. The assist device is provided with a pair of caster wheels engagable with the floor upon tilting thereof to permit ready movement to a position to receive the patient. The motor may be actuated by remote control and does not require a switch to be mounted on the device itself; however, it is within the contemplation of this invention that an actuation switch could be mounted on the assist device. The extent of rotation may be controlled by the actuating mechanism to stop at any desired angular movement between 0° and 360° to the left and 360° to the right.
Under a further embodiment, the steadying members mounted on the rotatable platform for gripping by the patient are designed such that opposing side members may be folded toward the end member connected thereto and the thus folded side members and end members pivoted about pivot connectors secured to the rotatable platform. This permits the device to be readily collapsed for storage or transportation to another site while insuring that the steadying members at all times remain with the rotatable platform. This feature of the invention is useable with a non-powered as well as a powered rotatable platform.
Referring to the drawings there is shown the medical assist device 10 of the present invention including a base 12 on which is mounted a rotatable platform 14 on which a patient being relocated from one support to a second support may stand. The rotatable platform 14 rotates about a first axis A-A and includes a rotatable disk 18 to which is adhered a pad 16 formed of rubber or other suitable material which will minimize the risk of the patient slipping thereon and which may have a series of protuberances 17 to provide additional anti-slip means. The platform 14, including its rotatable disk 18, is rotatable relative to the base 12.
The rotatable disk 18 has an outer peripheral edge 19 positioned to be engaged by a power driven disk 20 mounted on a rotatable shaft 22 of an electric motor 24 mounted on the base 12. (See
As can be seen in the enlarged fragmentary sectional view of
The circumferential edge 27 of the wheel rubber 26 is disposed at an angle relative to the axis A of the motor shaft 22, tapering inwardly toward the axis A in a direction from the bottom facing the floor upwardly toward the motor 24 and rotatable platform 14. Preferably, the included angle between the tapered edge 27 and the axis A is in the range of 0.5° to 7°; however, it could be significantly larger and could be more than 60°.
The outer peripheral edge 19 of the rotatable disk 18 is tapered at a mating angle with the circumferential edge 27 of the wheel rubber 26. Thus, the edge 19 tapers at a preferred angle of 0.5° to 7° outwardly from the axis A-A about which it rotates in a direction from the bottom facing the floor upwardly toward the platform 14 and pad 16 on which the patient stands. As is the case with the angle of the circumferential edge 27, the angle of the peripheral edge 19 relative to the axis A-A could be much larger, even more than 60°. As will be appreciated, at the line of contact between the peripheral edge 19 and the circumferential edge 27, the peripheral edge 19 will be tapering inwardly toward axis A and preferably at substantially the same angle as the edge 27 in order to assure mating engagement therebetween. This may be clearly seen in
More importantly, the feature of disposing the edges 19 and 27 at the angles as described will serve as a means for causing increased force of engagement of the edge 19 against the edge 27 when a patient stands near the outer periphery of the support platform 14. The weight of the patient will impart a force downwardly on the rotatable disk 18 and its edge 19 thereby forcing the edge 19 more tightly against the edge 27 than is the case when no patient is standing on the rotatable platform 14. As will be appreciated, if the edges 19 and 27, along the line of contact, were disposed at an angle tapering away from the axis A of the motor shaft 22 in a direction from the bottom facing the floor toward the support platform 14, the weight of any patient standing on the support platform 14 would have a tendency to cause the edge 19 to separate from the edge 27 upon downward deflection caused by the weight of a patient.
The rotatable disk 18 is supported on a lower housing 28 which is an integral part of the base 12. The lower housing 28 has a plurality of integrally molded reinforcing ribs 30 extending radially outwardly from its axis A-A. A plurality of rubber feet 32 are mounted on the lower housing 28 for resting on the floor in a non-slip relationship.
In order to permit ease of movement of the assist device 10 from one location to another preparatory to receiving a patient, there is provided a pair of rotatable wheels 33 supported on the base 12. As may be seen in
The rotatable disk 18 is rotatably supported on the lower housing 28 by means of a low profile ball bearing turntable 40 such as that sold by McMaster-Carr under its part number 6031K18 or 6031K19. The low profile ball bearing turntable 40 includes a lower plate 41 which is secured by fasteners 42 to the lower housing 28 in an area encircling the axis A-A. The ball bearing turntable 40 also includes an upper plate 43 secured by fasteners 44 to the bottom of the rotatable disk 18. Ball bearings are housed in a circular race 46 thereby permitting the upper plate 43 to easily rotate relative to the lower plate 41.
Extending upwardly from the support platform 14 are a plurality of support posts 34 resting in support sockets 36 mounted on the support platform 14. The number and configuration of the support posts 34 may be varied as desired. As shown in
Cross members 35, disposed in parallel relationship to one another, each extend between a pair of support posts 34 to provide rigidity to the gripping structure. As shown in the drawings, the posts 34 flare outwardly and upwardly to the desired height and then bend to provide a pair of horizontal spaced apart gripping members 38 which are parallel to one another and parallel to the support platform 14. If desired, additional support may be provided by upstanding posts 39 secured to the cross members 35. An additional gripping member 37 extends between the additional supports 39 to provide a closed front for support device 10. The additional gripping member 37 is contoured to the shape of the patient. A support belt 47 is secured to one of the additional posts 39 and a receptacle 48 for receiving and securing the support belt 47 is mounted on the other additional post 39. The support belt 47 may be strapped around the waist or back of a patient so that the patient is restrained between the belt 47 and the gripping member 37. An additional contoured support member 49 may be mounted on the front support posts 34.
The support posts 34 may be engaged to the sockets 36 with any desired “quick-release” type connecting means. Similarly, the cross members 35 and gripping members 37, 38 can be secured with quick-release type connectors in order to permit the assist device 10 to be readily disassembled and placed in an automobile truck, other vehicle or shipping container for transport to another location.
The electric motor 24 may be connected to a power source by means of an electrical cord retained in a cord housing 50 from which a plug 52 for the cord is shown extending. The motor 24 is housed in a plastic protective cover 23. The cord housing 50 and the cover 23 for the motor 24 are designed to protect the motor, electrical cord and interconnections waterproof manner in order that the patient assist device 10 may be washed and sterilized without damage. The motor is a commercially available motor, for example, one such as that sold by Dayton Electric as its electric gear motor Model No. 6Z075, which has associated therewith a remote handheld controller 60 (shown schematically in
For an assist device intended for a less infirmed patient having agility to operate it himself/herself, the switch or other actuating means for motor 24 may be mounted on the assist device or otherwise placed within reach of the patient. Additionally, if desired, the assist device of the present invention could be battery powered.
Although the feature of utilizing a power driven disk, such as the disk 20, frictionally engaged to a peripheral edge of the rotatable support platform 14 is one means of powering rotation of the support platform and its rotatable disk, other means could be used.
Referring to
Referring to
Referring to
Mounted on the rotatable wheel 76 for rotation therewith is a patient support platform 82. The patient support platform extends radially outwardly beyond the outer periphery of the rotatable wheel 76 as defined by the gear teeth 77 extending circumferentially therearound. The support platform 82 lies on a plane substantially co-planar with the ridge 79 and extends radially outwardly a distance sufficient to leave only a small gap between its outer edge 83 and the ridge 79.
A plurality of sockets 84, 85, 86 and 87, for mounting posts or post segments of a patient steadying structure, are positioned in spaced apart locations on the support platform 82 near the outer edge 83. The sockets 84, 85, 86 and 87 are semicircular in configuration. The two socket 86 and 87 which are closest to the housings 80B and 80A, respectively, have edges 86A and 87A respectively, each of which defines an opening, with the edges 86A and 87A being oriented such that the respective openings defined thereby face each other. In contrast, the sockets 84 and 85, which also have a semicircular configuration, have edges 84A and 85A, respectively, which define openings which face toward the sockets 86 and 87, respectively. The sockets 84 and 85 are each provided with apertures 88 for receiving pins designed to extend through apertures of the support posts or post segments received therein. If desired, the sockets 86 and 87 could also be provided with apertures 91 for receiving pins extending through apertures in the respective posts or post segments supported therein.
As can be seen in
Also positioned in the cavity with the rotatable wheel 76 is a platform 95 on which is mounted an electric motor 96 for powering rotation of the rotatable wheel 76. The electric motor 96 is secured to the platform 95 by straps 99 extending thereover and bolts 100 affixed to the platform 95. The electric motor 96 powers the rotation of a worm gear 97 which is engaged to the gear teeth 77 of the rotatable wheel 76. The electric motor 96 has the capability of rotating the worm gear 97 either in a clockwise or a counterclockwise direction to thereby rotate the platform 82 in either a clockwise or counterclockwise direction. The radially extending reinforcing members 94 in the area between the housings 80A and 80B have ends which contact the platform 95 on which the motor is mounted to hold it firmly in position. A suitable type of electric motor which may be used for the motor 96 is one manufactured by Bühler Motor GmbH of Germany as its Model No. 1.61.077612.00.
As can be readily seen in
Referring to
The steadying structure includes four post segments 102, 103, 104 and 105 which are received respectively in sockets 84, 85, 86 and 87. For purposes of this specification, post segments 102 and 103 will be referred to as the front post segments and post segments 104 and 105 will be referred to as the rear post segments. The front post segments 102 and 103 are fastened in their respective sockets 84 and 85 by means of pins 90 extending through apertures 88 (see
Telescopically received in front post segment 102 and rear post segment 104 is first side member 150. A second side member 152 is telescopically received in the opposing post segments, namely, front post segment 103 and rear post segment 105. Each of the side members 150, 152 is generally U-shaped with an outwardly extending bowed portion 150A and 152A.
The side member 150 has a rear leg portion 150B engaged to post segment 104 and a front leg portion 150C engaged to post segment 102. Similarly, the side member 152 has a rear leg portion 152B engaged to post segment 105 and a front leg portion 152C engaged to post segment 103.
Extending between the leg portions 150B and 150C is a connector member 106. The connector member 106 has a bracket 107 engaged to the rear leg portion 150B and a sleeve shaped receptacle 108 which receives the front leg portion 150C. The receptacle 108 has an internal configuration which serves the dual function of permitting the leg segment 150C to be rotated therein while being supported therein and at the same time for receiving a leg portion of the front member as hereinafter described.
The front member 156 is U-shaped and has a cross piece 157 with a central gripping section 158 lying generally in a horizontal plane for ease of gripping by a patient. Extending downwardly from the cross piece 157 are a pair of spaced apart leg portions 159 each having a series of apertures 161 for use in adjusting the height of the central gripping section 158. The leg portions 159 are tubular and are sized to receive in telescoping relationship a joinder member 162 having a cylindrical upper section 163 which is slideably received in the leg portion 159 and a lower section 164 which is curved and contoured at its free end to be received in the upper end of the sleeve 108 of the connector member 106. The front leg portion 150C which is also received in the sleeve 108 may be rotated therein and rotated relative to that portion of the lower section 164 of the joinder member 162. The upper cylindrical section 163 has apertures which may be aligned with the apertures 161 of the leg portions 159 and fitted with a pin or other fastening elements for connecting at the desired height of the central gripping portion 158. A similar connector member 106 is provided for engagement with the leg portions 152B and 152C of the opposing side member 152.
If desired, an additional reinforcing member 170 may be provided to add to the stability of the medical assist device. As can be seen in the drawings, the reinforcing member 170 may be a one piece member having a front 170A extending in between the upper cylindrical sections 163 of the joinder member 162 and a pair of side portions 170B extending between such upper cylindrical sections 163 and the cylindrical portions 150A of side member 150 and a similar cylindrical section of side member 152. The side portions 170B extend to gripping portions 170C engaged to the side members 150 and 152.
If desired, the forward post segments 104 and 105 may be fastened in their respective sockets 86 and 87 with pin connectors 165; however, it will be readily appreciated that such pin connectors 165 must be removed prior to collapsing the support structure in preparation for transporting it to another location.
When in use for assisting a patient to be moved from a bed to a chair or other support device, the medical assist device has the steadying structure with the side members 150 and 152 open as shown in
As will be appreciated, the unit may now be easily transported to a different location or different medical facility while occupying a minimum of space.
As will be appreciated, the collapsible support structure can be used on a medical assist device which is powered as shown in
Referring to
The platform 95A is provided with an ear 201 in the area adjacent the motor 96. The ear 201 has an aperture 202 in which is positioned a pivot pin which is secured to the bottom 74. The platform 95A is able to pivot about the pivot pin extending into the aperture 202 from a position shown in full lines in
At the opposing end of the platform 95A there is provided a bracket 205 with an ear 206 to which is secured a tension spring 207. The opposing end of the tension spring 207 is fastened to a fixed base member 208 by a screw 209. The tension on the tension spring 207 is sufficient to keep the worm gear 97 engaged to the gear teeth 77 during normal operation but a strength which will yield to permit the platform 95A to pivot outwardly to disengage the worm gear 97 from the gear teeth 77 in the event of a jam up preventing rotation of the rotatable wheel 76.
As will be appreciated, under this embodiment, radially extending reinforcing members 94A are shorter than the reinforcing members 94 of the embodiment of
Although the resilient means for yieldingly holding the worm gear 97 mounted on platform 95A in engagement with the gear teeth 77 has been described as a tension spring 207; it will be appreciated that other means may be provided for yieldingly urging the platform 95A to a position at which the worm gear will engage the gear teeth 77. Such other means could include a compression spring pushing against the side of the platform 95A facing away from the gear teeth.
The above detailed description of the present invention is given for explanatory purposes. It will be apparent to those skilled in the art that numerous changes and modifications can be made without departing from the scope of the invention. Accordingly, the whole of the foregoing description is to be construed in an illustrative and not a limitative sense, the scope of the invention being defined solely by the appended claims.
This application is based on and claims the benefit of U.S. Provisional Patent Application No. 60/503,984 filed Sep. 19, 2003.
Number | Date | Country | |
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60503984 | Sep 2003 | US |