This disclosure relates generally to devices and methods for transferring an object from a position on a first surface, onto a platform of the device, and then onto a second surface (or back to the first surface).
Countries around the world are facing an aging problem whereby in the coming decades, the majority of their populations will become dependents rather than of an independent age contributing to society. Coupled with this aging population is a growing number of people that have restricted mobility due to injury, illness, or old age. Being mobile necessitates a means of transportation (from point A to point B) as well as being transferred (from surface A to surface B).
There are various transportation aids that are often used to aid mobility. Examples include walkers, wheelchairs, slings, transfer boards and gantry hoists. Many of these devices have not been updated or improved in decades and as a result, fundamental problems associated with the operation of these transfer methods persist. These included injuries to practitioners, reduced patient health and well-being as a result of interaction with these devices, and induced stress on the health-care sector due to implications of the operation of these devices.
The fact however, is that these devices are greatly needed, as between 30% to 60% of patients in long-term care facilities need assistance with transfer to perform routine tasks such as eating a meal or going to the washroom. Without the aid of these devices, people would remain largely immobile once their health starts to fail. Similar challenges exist when performing routine medical diagnostics or conducting routine transfers with bariatrics patients. In these circumstances some transfers that may be required include (but not limited to), from a gurney to a medical imaging table (e.g. the bed of an MRI or CT scanner), movement of a patient temporarily to perform routine operations (e.g. bed cleaning, obtaining a weight measurement for the patient), or simply re-positioning of their body on their existing surface.
Currently the most popular devices used to assist in patient transfer consist of variations of lifts, slings, and transfer boards and sheets. The lifts among these systems are commonly referred to by their trade name as Hoyer Lifts, Hoyer being a popular manufacturer of these devices. These lifts have been in the market for decades with most innovations focusing on improving or re-packaging existing lift technologies. Current technologies typically place significant strain on a human operator, as they typically require some form of “staging” where a sling (or other strap(s) or harnesses) must be inserted underneath a patient, and then removed from under the patient after a transfer. Furthermore, these devices are often costly and may put heavy burdens on operating budgets of long-term care and health care facilities. These devices are also error prone, which often results in numerous injuries to the individuals being transferred, and in some cases has even resulted in death.
Disclosed is a transfer device having a device body with a first end, a second end, a first side, and a second side. The transfer device also has a transfer platform including a platform plate and a platform lateral actuator. The platform lateral actuator is configured to selectively move the platform plate laterally relative to the device body, such that the platform plate can be moved between a plurality of positions including (i) a stowed position in which the platform plate is retracted relative to the device body, (ii) a first extended position in which a first transverse edge of the platform plate is a leading edge that extends outward from the first side of the device body, and (iii) a second extended position in which a second transverse edge of the platform plate is a leading edge that extends outward from the second side of the device body. The transfer device also has a transfer belt having a first end secured to a first driven roller, a second end secured to a second driven roller, the belt extending from the first driven roller, around the first transverse edge of the platform plate, above an upper surface of the platform plate, around the second transverse edge of the platform plate, and to the second driven roller. The transfer device also has a first motor configured for driving the first driven roller, and a second motor configured for driving the second driven roller independent of the first driven roller. The transfer device also has a treatment system configured to apply a cleaning and/or disinfecting treatment to at least one of the transfer belt and the platform plate.
The transfer belt can make it possible to load an object onto the transfer platform and/or unload the object from the transfer platform without having to manually manipulate the object. At the same time, the transfer platform of the transfer device can support two-sided functionality, which can be useful when moving an object such as a patient from a first surface onto the transfer platform and then onto a second surface. This is a notable improvement over transfer platforms which do not support two-sided functionality.
In some implementations, the transfer belt is a first transfer belt and the transfer device also has a second transfer belt extending below a bottom surface of the platform plate on the first side of the device body, and a third transfer belt extending below a bottom surface of the platform plate on the second side of the device body. The second and third transfer belts can help avoid or mitigate friction between the first transfer belt and an upper surface holding or receiving the object.
In some implementations, the transfer device has a locking mechanism to selectively detach and attach the second transfer belt and the third transfer belt from and to the platform plate. The second and third transfer belts can selectively attach and detach in order to enable the platform plate and the first transfer belt to dynamically cross-over-center from the first side of the device body to the second side of the device body, and vice-versa, even while there is a patient or object on top of the platform plate. The second and third transfer belts can also be detached for example for cleaning or maintenance purposes.
Other aspects and features of the present disclosure will become apparent, to those ordinarily skilled in the art, upon review of the following description of the various embodiments of the disclosure.
For a better understanding of the described embodiments and to show more clearly how they may be carried into effect, reference will now be made, by way of example, to the accompanying drawings in which:
It should be understood at the outset that although illustrative implementations of one or more embodiments of the present disclosure are provided below, the disclosed systems and/or methods may be implemented using any number of techniques. The disclosure should in no way be limited to the illustrative implementations, drawings, and techniques illustrated below, including the exemplary designs and implementations illustrated and described herein, but may be modified within the scope of the appended claims along with their full scope of equivalents.
The drawings illustrate example embodiments of a transfer device 100, which can be used to move a human body (or other object) from a first location to a second location and/or to re-position the human body (or other object) on a surface. An overview of the transfer device 100 is provided in this section with reference
With reference to
The platform lateral actuator is configured to selectively move the platform plate 210 laterally relative to the device body, such that the platform plate 210 can be moved between a plurality of positions including (i) a stowed position in which the platform plate 210 is retracted relative to the device body, (ii) a first extended position in which a first transverse edge 213 of the platform plate 210 is a leading edge that extends outward from the first side 113 of the device body, and (iii) a second extended position in which a second transverse edge 224 of the platform plate 210 is a leading edge that extends outward from the second side 114 of the device body.
With reference to
In the position shown in
In the position shown in
In some implementations, the transfer platform 250 and 250a-b is covered by the transfer belt 150, including when it is being extended outward from the device body 110 and retracted back towards the device body 110. The transfer belt can make it possible to load an object onto the transfer platform and/or unload the object from the transfer platform without having to manually manipulate the object.
In some implementations, the transfer belt 150 is driven using one or more actuators such that, when the transfer platform 250 and 250a-b is being extended outward from the device body 110 or retracted back towards the device body 110, a top surface of the transfer belt 150 is not moving and excess slack in the transfer belt 150 is avoided or mitigated. In some implementations, as described in further detail below, the transfer belt 150 has a first end secured to a first driven roller, a second end secured to a second driven roller, such that the belt extends from the first driven roller, around the first transverse edge of the platform plate 210, above an upper surface of the platform plate 210, around the second transverse edge of the platform plate 210, and to the second driven roller.
In some implementations, as described in further detail below, the transfer belt 150 is a first transfer belt, and the transfer device 100 also has a second transfer belt extending below a bottom surface of the platform plate 210 on the first side of the device body, and a third transfer belt extending below a bottom surface of the platform plate 210 on the second side of the device body. The second and third transfer belts can help avoid or mitigate friction between the first transfer belt and an upper surface holding or receiving the object.
In some implementations, the transfer device 100 has a locking mechanism to selectively detach and attach the second and third transfer belts from and to the platform plate 210, in order to enable the platform plate 210 and first transfer belt 150 to dynamically cross-over-center from the first side 113 of the device body 110 to the second side 114 of the device body 110, and vice-versa, even while there is a patient or object on top of the platform plate 210. The second and third transfer belts can also be detached for example for cleaning or maintenance purposes. Further example details of the locking mechanism are provided later with reference to
In some implementations, the transfer device 100 has a belt treatment system which can be used to clean or sterilize the first transfer belt 150, the second transfer belt and/or the third transfer belt. Further example details of the belt treatment system are provided below.
In some implementations, the transfer device 100 has a platform plate treatment system which can be used to clean or sterilize the platform plate 210 of the transfer device 100. Further example details of the platform plate treatment are provided below.
As shown in
In some implementations, as can be seen from
In another implementation, the transfer device 100 has a nested drawer system and telescoping actuator (not shown) enabling further extension of the transfer platform 250 in the first and second extended positions, such that the platform plate 210 extends outward by a distance that is greater than the width of the device body by 10% to 110%. For example, if the width of the device body 110 is between WD=400 mm to 1250 mm, the transfer platform 250a can extend by a distance of between Dextend_1=440 mm to 1600 mm, providing an overall platform width of about Wextend_1=840 mm to 2850 mm. In some implementations, there are corresponding measurements for the transfer platform 250b in the other direction.
Enabling the transfer platform 250a-b to extend by more than the width of the device body 110 may have one or more advantages. For example, this may facilitate maneuvering the transfer device 100 through tight hallways, and/or may reduce the storage footprint of the transfer device when the transfer platform is retracted. This is made possible by the nested drawer system and telescoping actuator as noted above.
A relatively narrow width WD can advantageously facilitate maneuvering the transfer device 100 and/or reduce its storage footprint. However, in some cases it may be desirable for the transfer device 100 to have a supported (i.e. non-cantilevered) surface that has a relatively wider width Wo. For example, the device body 110 can have a wider non-cantilevered support surface to provide increased comfort and/or safety when transporting a patient between locations by moving the transfer device 100 across a floor surface.
In some implementations, the transfer device 100 has a support structure 188 configurable to adjust a height of the device body 110 above the floor surface F and/or an angle of the device body 110. In some implementations, the support structure 188 can adjust height and tilt of the device body 110 in both the long and short axis. In some implementations, the support structure 188 has actuators coupled to a transfer device controller for controlling the height and/or the tilt of the device body 110. This can allow for changes in an angle of approach of the transfer platform in advance of or during transfer in order to reduce reactionary forces on the device, reduce the pressure applied to the patient (or object) being transferred or allow for medically advantageous positions when a patient is on the transfer platform such as Trendelenburg or reverse Trendelenburg position. The actuation of these support actuators may be controlled by a main transfer device controller or separately by its own controller and operate in parallel through electronic communication with the transfer controller.
Referring back to
In some implementations, the transfer device 100 has at least one control panel coupled to the transfer device controller to allow a user to operate the transfer device 100. For example, with reference to
In some implementations, the transfer device 100 has a transfer device controller 180, which can control one or more actuators (e.g. motors) such as the platform lateral actuator of the platform plate 210 to extended or retract the transfer platform 250 and 250a-b. In some implementations, the first driven roller and the second driven roller for the transfer belt 150 are operably coupled to the transfer device controller 180, and the transfer device controller 180 is configured to selectively actuate the first driven roller and the second driven roller concurrently or separately from each other. In this way, the transfer device controller 180 can control slack of the transfer belt 150. The transfer device controller 180 can also control the belt treatment system and/or the platform plate treatment system.
In some implementations, the transfer device controller 180 is coupled to one or more sensors of the transfer device 100, and utilizes data from the sensors when operating the transfer device 100. In some implementations, the controller synchronizes and directly controls the transfer device 100 with its subsystems, provides feedback to the user in regards to a state of the transfer device 100, and uses the state it is monitoring in order to provide safe operation (e.g. shutting the system down automatically if the transfer device 100 is operating in an unsafe manner).
In some implementations, the transfer device controller 180 is a single controller (e.g. single microcontroller) configured to handle all controllable subsystems of the transfer device 100. In other implementations, the transfer device controller 180 includes multiple controllers (e.g. separate microcontrollers) for handling the controllable subsystems of the transfer device 100. Thus, the term “transfer device controller” covers one or more controllers (e.g. one or more microcontrollers). The purpose for utilizing more than one controller may be to reduce sensor transmission lengths, increase redundancy and/or locate the controllers advantageously, physically within the transfer device 100 to reduce latency. Multiple controllers may also be utilized due to practical limitations of current state of the art controllers (e.g. number of available General Purpose Input Outputs). For example, a first controller may be placed on the first end 101 and a second controller may be placed the second end 102 to capture signals from sensors mounted on each end independently.
There are many possibilities for the controllable subsystems of the transfer device 100. As described herein, some possibilities for the controllable subsystems can include platform lateral actuator(s), driven roller(s) for transfer belt(s), a belt treatment system, and/or a platform plate treatment system. Additional or other controllable subsystems may be possible.
In some implementations, the one or more actuators controlled by the transfer device controller 180 are powered via a battery, which can help to enable the transfer device 100 to be portable. For example, with reference to
The examples described herein generally focus on the transfer device 100 having a transfer device controller 180, which is configured to control the transfer platform, and optionally provides additional functionality as described herein. However, in another embodiment, the transfer device 100 can be implemented without any transfer device controller 180. For instance, the transfer device 100 could be entirely analogue and designed to function without a device controller.
Example operation of the transfer device 100 in transferring a human body from a first surface to a second surface will now be described with reference to
The transfer device 100 is positioned between the gurney 20 with the human body to be transferred and the bed 30, e.g. in the position shown in
Referring to
In some implementations, the motion of transfer platform 250 and/or the transfer belt 150 is controlled to provide limited (or zero) relative motion between an upper surface of transfer platform 250 (i.e. the transfer belt 150) and the human body 10 during some or all of the transfer. In this way, the transfer platform 250 can be extended outward and under the human body 10 as shown in
Optionally, a lower surface of a guard layer (e.g. guard layer 155 as described later, not shown in
In some implementations, to enable limited relative motion between the upper surface of transfer platform 250 (i.e. the transfer belt 150) and the human body 10 while the transfer platform 250 is being extended outward from the transfer device 100 (i.e.
Preferably, driven rollers (e.g. driven rollers 160a and 160b as described later, not shown in
Referring to
While the human body 10 is being moved from the gurney 20 towards the transfer device 100 (
Referring to
With reference to
It will be appreciated that, in use, at least some, preferably most, and more preferably substantially all of the transfer platform 250 is supported vertically by a surface onto which an object is to be transferred using the transfer platform 250, or a surface from which an object to be transferred is resting. In the illustrated example, the transfer platform 250 receives vertical support from the gurney 20 (
To transfer the patent 10 from the bed 30 to the gurney 20, the process illustrated in
As noted above, there can be friction between the transfer belt 150 and the surface of the gurney 20. While low friction bed sheets can reduce or mitigate such friction, other implementations are possible in which such friction can be largely avoided, because contact between the transfer belt 150 and the surface of the gurney 20 can be mitigated or avoided completely. For example, in other implementations, the transfer device 100 has a second transfer belt (not shown) extending below a bottom surface of the transfer platform 250 when the transfer platform 250 is extended outward, such that the second transfer belt provides limited or zero relative motion between the bottom surface of the transfer platform 250 and the surface of the gurney 20. Such an implementation is briefly described below with reference to
With reference to
Therefore,
While the embodiments disclosed herein are described specifically in relation to and in use with transferring a human body (e.g. an individual with reduced, limited, or no mobility, an able bodied individual, an unconscious individual, an incapacitated individual, etc.), it will be appreciated that the embodiments disclosed herein may additionally or alternatively be used to transfer other objects, such as those that may be bulky, cumbersome, delicate, and/or difficult to grasp and move. For example, the embodiments disclosed herein may be suited and/or adapted for use to transfer livestock or domestic animals, undomesticated animals (e.g. in a zoo or wildlife care facility), human corpses (e.g. in a funeral home of a mortuary), inanimate objects (e.g. in courier, cargo, and/or logistical operations), and the like.
Example implementation details of the transfer device 100 are provided in this section with reference to
With reference to
With reference to
Utilizing a discontinuous transfer belt 150 may have one or more advantages. For example, this may facilitate the removal and/or replacement of the transfer belt 150 (e.g. by removing a driven roller with the transfer belt attached). This may result in the transfer device 100 being relatively easy to clean and/or maintain, which may result in reduced downtime. This may be of particular importance in use cases where cross-contamination is of concern (e.g. in hospitals, care homes, etc.).
Additionally, or alternatively, using a discontinuous belt with driven rollers on both ends may also have a mechanical advantage, in that the transfer belt's tension can be controlled from both ends of the belt. For example, this may assist in providing a desired tension level, and/or a desired level of ‘slack’ (or a lack thereof) in transfer belt 150.
As shown schematically in
In the illustrated example, the transfer belt 150 is guided around two passive (i.e. non-driven) rollers 165a and 165b to maintain tension and to avoid potentially interfering interactions with other components located within the housing (e.g. control systems, motors and motor drivers, gears, and the like). It will be appreciated that fewer, more, or no tensioners 165a and 165b may be provided in alternative implementations.
In the illustrated example, the end drive assembly 300a, first and second belt drive sprockets 320a and 320d are driven by motors 390a and 390d, respectively. The belt drive sprockets 320a and 320d are connected to transfer belt roller sprockets 360a and 360b by drive belts 361a and 361b, respectively. Rotation of the transfer belt roller sprockets 360a and 360b results in rotation of the transfer belt rollers 165a and 165b, respectively. In the illustrated example, tension idlers 322a and 322b are also provided to control the tension of drive belts 361a and 361b, respectively. It will be appreciated that the tension idlers 322a and 322b are optional.
Also shown are platform drive sprockets 320b and 320c, which are driven by motors 390b and 390c, respectively. The platform drive sprocket 320b is connected via a drive belt 371a to a first series of segment drive sprockets 380a and 380b. The platform drive sprocket 320c is connected via a drive belt 371b to a second series of segment drive sprockets 380c and 380d. Idlers 323a and 323b are provided in order to control tension on the drive belt 371a, and idlers 323c and 323d are provided in order to control tension on the drive belt 371b.
As illustrated in
Turning to
An advantage of this design is that it may allow the linear displacement sensor 990 to provide a high resolution signal both at relatively low transfer belt tensions (e.g. when no objects are in contact with transfer belt 150 and/or transfer platform 250), and at relatively high transfer belt tensions (e.g. when a patient is being transferred on the transfer platform 250).
In the illustrated example, each tensioner 165a and 165b is passively sprung. Alternatively, each tensioner 165a and 165b may be actively actuated, e.g. by providing a linear actuator instead of, or in addition to, one or more passive springs. Additionally, or alternatively, each tensioner 165a and 165b may be actively dampened, e.g. using ferro-dampening fluids or the like. In some implementations, the relative position of each tensioner 165a and 165b may be determined by a positioning sensor (not shown) such as a Time of Flight (TOF) or linear potentiometer, for example. This determined tensioner position may be used e.g. by the transfer device controller to measure and/or infer tension within the transfer belt 150.
In some implementations, each driven roller 160a and 160b is driven using a corresponding motor. It will be appreciated that any suitable motor type (e.g. stepper motors, DC or AC motors, brushless DC (BLDC) motors, pneumatic rotary motors, direct electrical motors, and the like) may be used in one or more variant implementations. Additionally, or alternatively, other gearing (e.g. two or more stages, planetary gearing) may be used. During operation, it will be appreciated that corresponding motors or actuators may be driven independently or synchronously to suit the required function(s).
As discussed above, the transfer belt 150 passes around the first transverse edge 213 of the platform plate 210 and around the second transverse edge 224 of platform plate 210. Optionally, some or all of the first and second transverse edges 213 and 224 may be provided with one or more friction-reducing features. With reference to
In some implementations, with reference back to
With reference to
In the illustrated example, teeth of platform drive pinions 382a-d engage platform rack segments (not shown) provided on the underside of the ends of the platform plate 210. It will be appreciated that in one or more alternative implementations, the engagement between the end drive assembly 300a and the platform plate 210 may not include a rack and pinion arrangement. For example, platform drive rollers may have a compressible elastomer configured to provide a sufficiently high frictional coefficient between themselves and the undersides of the ends of the platform plate 210.
Enabling the motor hub assembly 380 to be modular may have one or more advantages. For example, allowing an entire set of motors and drive wheels to be ‘swapped out’ may facilitate easier maintenance and/or service of the transfer device 100, which may lead to reduced downtime of the transfer device 100.
In the examples illustrated in
With reference to
With reference to
In the illustrated example, the platform extension supports 570a-b are generally rectangular planar support surfaces. It will be appreciated that in one or more alternative implementations, platform extension supports may be of different shapes and/or may have different surface features. For example, one or more rollers may be provided on an upper surface of a platform extension support.
Also, in the illustrated example, the platform extension supports 570a-b may be manually moved between the positions shown in
Referring now to
With reference to
In some implementations, each end of the detachable member 225 has a spring-loaded magnet 226 that generally has two states: a first state shown in
It is noted that the spring-loaded magnet 226 is one of many possibilities for selectively securing the detachable member 225 to the device body 110. Referring now to
With reference to
In some implementations, with reference back to
In some implementations, with reference to
Note that the locking mechanisms depicted and described with reference to
In some implementations, the transfer device 100 includes one or more treatment systems (e.g. transfer belt treatment systems and/or platform plate treatment system) for applying a cleaning and/or disinfecting treatment to one or more of the transfer belts 150 and 170a-b and/or to the platform plate 210. There are many possibilities for the treatment systems. For example, as described in more detail below, the transfer device 100 can include one or more of ultraviolet (UV) treatment systems, fluid spray treatment systems, fluid bath treatment system, contact cleaning systems, or any combination thereof. Specific examples are described below with reference to
In some implementations, the transfer device 100 has at least one ultraviolet (UV) light emitter positioned within the device housing to continuously or selectively emit UV light towards an upper surface of the transfer belt 150, or both an upper surface and a lower surface of the first transfer belt 150, as it passes by the UV light emitter(s). Additionally, or alternatively, at least one UV light emitter is positioned within the transfer device 100 to continuously or selectively emit UV light towards the second and third transfer belts 170a-b as they pass by the UV light emitter(s). Additionally, or alternatively, at least one UV light emitter is positioned within the transfer device 100 to continuously or selectively emit UV light towards the platform plate 210 as the platform plate 210 pass by the UV light emitter(s). Such a configuration may be characterized as an ultraviolet germicidal irradiation system.
For example, with reference to
In some implementations, the transfer device 100 has at least one fluid emitter configured to direct at least one of a cleaning fluid and a disinfectant fluid towards at least the upper surface of the transfer belt, or both an upper surface and a lower surface of the first transfer belt 150, as it passes by the fluid emitter(s). Additionally, or alternatively, at least one fluid emitter is positioned within the transfer device 100 to continuously or selectively emit fluid towards an upper surface and/or a lower surface of the second and third transfer belts 170a-b as they pass by the fluid emitter(s). Additionally, or alternatively, at least one fluid emitter is positioned within the transfer device 100 to continuously or selectively emit fluid towards the platform plate 210 as the platform plate 210 pass by the fluid emitter(s).
For example, with reference to
In some implementations, the transfer device 100 has a fluid chamber defined within the housing interior, and a fluid agitator (e.g. an ultrasonic agitator or ultrasonic transducer) is provided therewith (e.g. inside the fluid chamber, coupled to an outside wall of the fluid chamber, or otherwise coupled to the fluid chamber) to continuously or selectively agitate a fluid within the fluid chamber as the first transfer belt 150 passes through the fluid chamber. Additionally, or alternatively, a fluid chamber and a fluid agitator provided therewith are positioned within the transfer device 100 to continuously or selectively agitate a fluid within the fluid chamber as the platform plate 210 passes through the fluid chamber. Such a configuration may be characterized as a fluid agitation system or as an ultrasonic bath system.
For example, with reference to
In some implementations, a brush, sponge, microfiber, or other material may be positioned within the housing and in contact with a surface of the first transfer belt 150, such that when the transfer belt is advanced or retracted, dirt or debris may be removed from an upper surface of the first transfer belt 150, or both an upper surface and a lower surface of the first transfer belt 150. For example, with reference to
Optionally, a reservoir of a cleaning and/or disinfectant fluid (e.g. alcohol, peroxide, bleach, etc.) may also be provided, for dispensing cleaning and/or disinfectant fluid onto the brush, sponge, microfiber, or other material, and/or directly onto the first transfer belt 150.
In some implementations, contact treatment can be combined with one or more other treatments for cleaning and/or disinfecting the platform or transfer belts. For example, with reference to
Although a specific configuration with three fluid chambers 521-523 and three fluid agitators 524-526 is shown in
It will be appreciated that for implementations that include a fluid dispensing apparatus, ‘fluid-proofing’ or at least increased ingress protection may be implemented for fluid-sensitive parts of the device (e.g. electronics).
In some implementations, the transfer belt treatment system is operably coupled to the transfer device controller 180, and the transfer device controller 180 is configured to selectively actuate one or more of the UV light emitter 501-507, the fluid emitter 511-517, and the fluid agitator 524-256 concurrently or separately from each other. In some implementations, the transfer device controller is also operatively coupled to the platform plate treatment system, and the transfer device controller 180 is configured to selectively actuate one or more of the UV light emitter 501-507, the fluid emitter 511-517, and the fluid agitator 524-256 concurrently or separately from each other.
In some implementations, a manual actuator (e.g. a depressible button) may be provided to selectively actuate the transfer belt treatment system to provide one or more treatments (e.g. UV light, disinfectant fluid, ultrasonic bath agitation, contact treatment) to the transfer belt 150. For example, the UV light emitter may be configured such that, in response to depression of the manual actuator, it emits UV light for a pre-set period of time (e.g. 10 seconds, 30 minutes), which may be selected based on e.g. the decontamination level required, a distance of the emitter from belt 150, the intensity of light emitted by the emitter, and/or other factors known to those in the art. As another example, the agitator may be configured such that, in response to depression of the manual actuator, it agitates fluid in the chamber fora pre-set period of time (e.g. 10 seconds, 30 minutes), which may be selected based on e.g. the decontamination level required, composition of fluid within the chamber, and/or other factors known to those in the art. Additionally, or alternatively, the transfer belt treatment system may be configured such that one or more treatments (e.g. UV light, disinfectant fluid, ultrasonic agitation, contact treatment) are provided at pre-set intervals (e.g. following every transfer operation, every 24 hours) without requiring manual actuation, and/or at a preset time after a transfer operation has been performed.
Numerous modifications and variations of the present disclosure are possible in light of the above teachings. It is therefore to be understood that within the scope of the appended claims, the disclosure may be practised otherwise than as specifically described herein.
This patent application is a CIP (Continuation in Part) application of U.S. patent application Ser. No. 17/708,439 filed on Mar. 30, 2022. Priority is claimed from U.S. patent application Ser. No. 17/708,439 filed on Mar. 30, 2022, the entire disclosure of which is incorporated by reference.
Number | Date | Country | |
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Parent | 17708439 | Mar 2022 | US |
Child | 18061937 | US |