The present disclosure generally relates to systems and methods for managing moisture for medical devices, and more particularly to moisture management for medical devices having a supply connection for receiving gas.
The present disclosure generally relates to medical devices having connections to external gas supplies, such as anesthesia machines and ventilators, for example. Anesthesia machines are medical devices known in the art used to deliver a mix of gases and anesthetic agents to a patient for the purposes of inducing and maintaining anesthesia. An exemplary anesthesia machine presently known in the art is the Aisys CS2 by GE Healthcare®. Similarly, a ventilator is a medical device that provides mechanical ventilation to move air in and out of the lungs of a patient, which may be used alone or in conjunction with the functions described above when incorporated with an anesthesia machine. An exemplary ventilator presently available in the market is the Carescape R860 Ventilator by GE Healthcare®.
In each case, the medical device is typically connected to an incoming gas supply connection, which in the example of use in a hospital context may include medical-grade oxygen to be delivered to the patient. The oxygen may be mixed with other gases and/or anesthetic agents as needed.
This Summary is provided to introduce a selection of concepts that are further described below in the Detailed Description. This Summary is not intended to identify key or essential features of the claimed subject matter, nor is it intended to be used as an aid in limiting the scope of the claimed subject matter.
One embodiment of the present disclosure generally relates to a moisture management system for a medical device having a supply connection for receiving gas and a patient connection for supplying the gas to a patient, The system includes a water trap having an inlet, an outlet, a first reservoir, and a drain, the inlet receiving the gas from the supply connection and the outlet returning the gas to the patient connection, where the water trap is configured to remove moisture from the gas flowing from the inlet to the outlet, and where the moisture removed is held in the first reservoir. The system further includes an evaporation chamber having an inlet, an exhaust, and a second reservoir, where the inlet is fluidly coupled to the drain of the water trap to receive the moisture from the first reservoir, where the moisture is subsequently held in the second reservoir, and where the evaporation chamber is configured such that the moisture evaporates from the second reservoir and exits as vapor via the exhaust. An evaporator increases a rate at which the moisture in the second reservoir evaporates via the exhaust.
In certain embodiments, the evaporator is a fan that blows air across the moisture in the second reservoir to increase the rate of evaporation from the evaporation chamber.
In certain embodiments, the evaporator is a wick positioned to draw the moisture upwardly from the second reservoir to increase the rate of evaporation from the evaporation chamber.
In certain embodiments, the evaporator is a heater positioned in the second reservoir such that the heater warms the moisture therein to increase the rate of evaporation from the evaporation chamber.
In certain embodiments, the heater is a PTC heater.
In certain embodiments, the heater is configured to remain at or below 50° C.
In certain embodiments, the system further includes a first level sensor positioned to detect when the moisture in the first reservoir exceeds a first threshold, and a drain valve fluidly coupled between the drain of the water trap and the inlet of the evaporation chamber to control flow therebetween, where the drain valve is normally closed. The system further includes a control system coupled to the first level sensor and the drain valve, where the control system causes the drain valve to open while the first level sensor detects that the moisture in the first reservoir exceeds the first threshold.
In certain embodiments, the system further includes a bypass valve that bypasses the water trap to fluidly couple the supply connection and the patient connection, where the bypass valve is normally closed, and where the control system further causes the bypass valve to open while the first level sensor detects that the moisture in the first reservoir exceeds the first threshold.
In certain embodiments, the system further includes a first water trap valve fluidly coupled between the supply connection and one of the inlet and the outlet of the water trap to control flow therebetween, where the first water trap valve is normally open, and where the control system further causes the first water trap valve to close while the first level sensor detects that the moisture in the first reservoir exceeds the first threshold.
In certain embodiments, the first water trap valve is fluidly coupled between the supply connection and the inlet of the water trap, further including a second water trap valve fluidly coupled between the outlet of the water trap and the patient connection to control flow therebetween, where the second water trap valve is normally open, and wherein the control system further causes the second water trap valve to close while the first level sensor detects that the moisture in the first reservoir exceeds the first threshold.
In certain embodiments, the evaporator is a powered device, further including a second level sensor positioned to detect when the moisture in the second reservoir exceeds a second threshold, where the control system increases the power to the evaporator while the second level sensor detects that the moisture in the second reservoir exceeds the second threshold.
In certain embodiments, the system further includes a second level sensor positioned to detect when the moisture in the second reservoir exceeds a second threshold, and also a control system coupled to the second level sensor and the evaporator, where the evaporator is a powered device, and where the control system increases the power to the evaporator while the second level sensor detects that the moisture in the second reservoir exceeds the second threshold.
In certain embodiments, a UV light is positioned to irradiate the moisture within at least one of the first reservoir and the second reservoir.
In certain embodiments, at least one of the first and second reservoirs is configured to be antibacterial.
In certain embodiments, the supply connection supplies the gas to the patient from an anesthesia machine and the patient connection receives the gas from the patient back to the anesthesia machine.
Another embodiment generally relates to a method for managing moisture for a medical device having a supply connection for receiving gas and a patient connection for supplying the gas to a patient. The method includes fluidly coupling a water trap to the primary conduct, the water trap having an inlet, an outlet, a first reservoir, and a drain, the inlet receiving the gas from the supply connection and the outlet returning the gas to the patient connection, where the water trap is configured to remove moisture from the gas flowing from the inlet to the outlet, and where the moisture removed is held in the first reservoir. The method includes fluidly coupling an evaporation chamber to the drain of the water trap, the evaporation chamber having an inlet, an exhaust, and a second reservoir, where the inlet is fluidly coupled to the drain of the water trap to receive the moisture from the first reservoir, where the moisture is subsequently held in the second reservoir, and where the evaporation chamber is configured such that the moisture evaporates from the second reservoir and exits as vapor via the exhaust. The method further includes positioning an evaporator in proximity to the second reservoir such that the evaporator acts on the moisture within the second reservoir to increase a rate at which the moisture evaporates therefrom via the exhaust.
In certain embodiments, the method further includes positioning a first level sensor to detect when the moisture in the first reservoir exceeds a first threshold, fluidly coupling a drain valve between the drain of the water trap and the inlet of the evaporation chamber to control flow therebetween, where the drain valve is normally closed, and coupling a control system to the first level sensor and the drain valve and configuring the control system to cause the drain valve to open while the first level sensor detects that the moisture in the first reservoir exceeds the first threshold.
In certain embodiments, the method further includes fluidly coupling a bypass valve that bypasses the water trap to fluidly couple the supply connection and the patient connection, where the bypass valve is normally closed, fluidly coupling a first water trap valve between the supply connection and one of the inlet and the outlet of the water trap to control flow therebetween, wherein the first water trap valve is normally open, and configuring the control system to further cause the bypass valve to open and the first water trap valve to close while the first level sensor detects that the moisture in the first reservoir exceeds the first threshold.
In certain embodiments, the evaporator is a powered device, further comprising positioning a second level sensor to detect when the moisture in the second reservoir exceeds a second threshold, and further comprising configuring the control system to increase the power to the evaporator while the second level sensor detects that the moisture in the second reservoir exceeds the second threshold.
Another embodiment generally relates to a moisture management system for a medical device having a supply connection for receiving gas and a patient connection for supplying the gas to a patient. The system includes a water trap having an inlet, an outlet, a first reservoir, and a drain, the inlet being coupled via a first water trap valve to the supply connection for receiving the gas therefrom, the outlet being coupled via a second water trap valve to the patient connection for supplying the gas thereto, where the first and second water trap valves are normally open, where the water trap is configured to remove moisture from the gas flowing from the inlet to the outlet, and where the moisture removed is held in the first reservoir. The system includes an evaporation chamber having an inlet, an exhaust, and a second reservoir, where the inlet is fluidly coupled via a drain valve to the drain of the water trap to receive the moisture from the first reservoir, where the drain valve is normally closed, where the moisture is subsequently held in the second reservoir, and where the evaporation chamber is configured such that the moisture evaporates from the second reservoir and exits as vapor via the exhaust. A bypass valve bypasses the water trap to fluidly couple the supply connection and the patient connection, where the bypass valve is normally closed. First and second level sensors are positioned to detect when the moisture in the first and second reservoirs exceeds first and second thresholds, respectively. A fan blows air across the moisture in the second reservoir to increase a rate of evaporation of the moisture from the evaporation chamber. A heater is positioned in the second reservoir such that the heater warms the moisture therein to increase the rate of evaporation from the evaporation chamber. A control system is coupled to the first and second level sensors, the bypass valve, the first and second water trap valves, and the drain valve, where the control system causes the bypass valve to open, the first and second water trap valves to close, and the drain valve to open while the first level sensor detects that the moisture in the first reservoir exceeds the first threshold, and where the control system increases the power to the evaporator while the second level sensor detects that the moisture in the second reservoir exceeds the second threshold.
Various other features, objects and advantages of the disclosure will be made apparent from the following description taken together with the drawings.
The present disclosure is described with reference to the following drawings.
The present disclosure generally relates to systems and methods for managing moisture in medical devices. Through experimentation and development, the inventors have recognized problems with respect to moisture management for medical devices presently known in the art, including but not limited to medical device having a supply connection connected to a gas supply that subsequently supply a gas mixture to a patient. Exemplary gases include oxygen, nitrogen, anesthetic agents, other atmospheric gases, and/or other mixtures thereof as presently known in the art. In particular, the inventors have recognized problems with moisture management for anesthesia devices and ventilators, which in a clinical setting are connected at their respective supply connections to wall gas at a hospital or clinic (providing oxygen or other gases), whereby the patient is then connected via hoses to a patient connection to receive a desired anesthetic mix of gases, ventilation support, or both.
The inventors have recognized that the incoming gas provided at the supply connection often introduces moisture into the medical device, which may be condensed water, oil from various compressors or facility equipment, or other contaminants in addition to the intended gas being supplied. This moisture can cause damage to many different components within the medical device, including from an electrical, mechanical, and/or chemical basis, for example. This moisture also introduces the opportunity for contamination in terms of pathogenic growth inside the medical device, which can then be transferred to the patient.
The inventors have recognized that a similar phenomenon occurs at the patient connector side of the medical device, whereby moisture is introduced into the medical device by virtue of the patient being connected to the patient connection via hoses. For example, moisture is introduced into the medical device via condensation of the patient's warm exhalation gases. As previously discussed, this can cause damage to the internal components of the medical device, and/or may introduce pathogens into the medical device. Unintended moisture also causes problems with seals becoming dirty, which over time impacts the performance thereof.
Certain medical devices presently known in the art provide water traps in an effort to collect this unintended moisture. This may include moisture entering the system from the supply connection, as well as moisture introduced from the patient. However, as is discussed further below, the inventors have found these presently known system to be woefully inadequate in preventing the damage and pathogenic risks described above, with most systems providing no preventative measure at all.
The medical device 2 includes a breathing system 12, which in certain examples includes a manual breathing bag 14. The breathing system 12 provides a flow of gas to the patient via a patient connection 10. As also shown in
In certain examples, as shown in
A similar zig-zag pattern may also be defined within the medical device 2 itself (i.e., to protect the medical device 2 in a similar manner as the cartridge system 30), typically just downstream of the supply connection 8. For medical devices presently known in the art that include such a zig-zag pattern, the condensed moisture is either lead to a tray within the inside of the medical device, or onto the floor of the room. These solutions either lead to a puddle on the floor, or another need for manual draining of the tray before overflowing, leading to the problems discussed above. Namely, manual intervention to drain various trays or traps is problematic in that a failure to do such manual draining results in moisture entering the medical device and/or breathing circuits, damaging equipment and/or introducing pathogens for the patient. Similarly, the drain system creates risks when overflowing, leading to water on the floor, for example.
Accordingly, the systems and methods presently disclosed solve the unmet needs of not only provide for collecting moisture from incoming supply lines and/or as introduced from the patient, but also eliminate the requirement for the manually draining this collected moisture. As is discussed further below, the systems and methods presently disclosed generally provide for collecting this moisture from the various sources, then vaporizing it to be harmlessly returned to the room automatically and as needed.
The moisture management system 40 includes a water trap 50 that extends between a top 52 and bottom 54. In the example shown, an inlet 56 and outlet 58 for communicating gas to and from the water trap 50, respectively, are each provided within the top 52 of the water trap 50. However, it should be recognized that the positioning of the inlet 56 and/or outlet 58 may be in alternate positions, for example on one of the sides of the water trap 50 between the top 52 and bottom 54. Conduits C1-C12 (see
With continued reference to
The moisture management system 40 further includes an evaporation chamber 70 that extends between a top 72 and bottom 74. An inlet 76 is provided in the top 72 of the evaporation chamber 70, which is fluidly coupled to the drain 68 of the first reservoir 60 in the water trap 50 (e.g., using the conduit C9 as discussed above). The evaporation chamber 70 also includes an exhaust 78. A second reservoir 80 is fluidly coupled to both the inlet 76 and the exhaust 78. As such, the moisture received from the water trap 50 via the inlet 76 of the evaporation chamber 70 is retained within the second reservoir 80, shown as the moisture 82 having a fill level 84.
With continued reference to
In the example shown in
In certain embodiments, an air funnel 90 is also provided within the evaporation chamber 70 to assist in concentrating the flow of air provided by the fan 120 through the exhaust 78. The air funnel 90 is comprised of a first wall 94 extending downwardly from the top 72 of the evaporation chamber 70, a second wall 96 substantially parallel to the top 72, and a third wall 97 connecting to the second wall 96 and also the top 72. In the configuration of
In the configuration of
As shown in
The embodiment of
The embodiment of
An exemplary method 200 for operating the configuration of
When the fill level does exceed a first threshold as determined in step 208, step 210 provides for opening the bypass and drain valves 144, 140, thereby enabling the moisture 62 within the first reservoir 60 of the water trap 50 to drain via the drain 68 and thereby enter the evaporation chamber 70. At the same time, step 212 provides for closing the first water trap valve 146 (and in the example of
In embodiments in which a powered device 110 is provided, this powered device (e.g., a fan 120 and heater 130) are turned on in step 214. It should be recognized that in certain embodiments, one or more of the powered devices 110 may remain operational at all times, and/or in these cases step 214 may provide for one or more of the powered devices 110 operating at a different power level. For example, the powered devices 110 may be controlled to increase a flow rate of the fan 120 and/or increase the heat produced by the heater 130 as the moisture is introduced from the water trap 50 to the evaporation chamber 70, and/or as a function of the fill level 84 as discussed below, for example.
Step 216 then provides for measuring with a second level sensor 86 the fill level 84 within the second reservoir 80 for the evaporation chamber 70. If it is determined in step 218 that the fill level 84 in the second reservoir 80 exceeds a second threshold, the process continues from steps 220 through 226. In the alternate, if the fill level is not determined to exceed the second threshold in step 218, the process returns to step 208.
When the fill level 84 in the second reservoir 80 exceeds the second threshold as determined in step 218, step 220 provides for opening the first water trap valve 146 (and in the embodiment of
The closure of the drain valve 140 is to prevent additional moisture 62 from entering the evaporation chamber 70 until the fluid level 84 within the second reservoir 80 once again returns to a fill level 84 below the second threshold. In other words, the drain valve 140 prevents the evaporation chamber 70 from being overfilled. The closure of the drain valve 140 also prevents evaporation of the moisture 82 from the evaporation chamber 70 back towards the water trap 50, particularly in embodiments that do not incorporate a one-way valve 142 as shown in
Once it is determined in step 224 that the fill level in the second reservoir 80 is at or below the second threshold, step 226 provides for turning off the power devices 110, or as previously described intentionally modifying one or more of the powered devices 110 to operate at a reduced power level.
It will be recognized that the one or more powered devices 110 need not operate at simply a two-step process (for example on versus off, or low power versus high power), but may also operate at intermediate levels depending on the measurements of the first level sensor 66 and/or second level sensor 86, for example.
In certain embodiments, the moisture management system 40 includes sanitization features for preventing bacterial, viral, fungal, or other deleterious growth or buildup within the system, for example, but not limited to within the water trap 50 and evaporation chamber 70. For example, in the embodiment of
In other embodiments, such as that shown in
In certain examples, the control system 300 communicates with each of the one or more components of the system 40 via a communication link CL, which can be any wired or wireless link. The control module 300 is capable of receiving information and/or controlling one or more operational characteristics of the system 40 and its various sub-systems by sending and receiving control signals via the communication links CL. In one example, the communication link CL is a controller area network (CAN) bus; however, other types of links could be used. It will be recognized that the extent of connections and the communication links CL may in fact be one or more shared connections, or links, among some or all of the components in the system 40. Moreover, the communication link CL lines are meant only to demonstrate that the various control elements are capable of communicating with one another, and do not represent actual wiring connections between the various elements, nor do they represent the only paths of communication between the elements. Additionally, the system 40 may incorporate various types of communication devices and systems, and thus the illustrated communication links CL may in fact represent various different types of wireless and/or wired data communication systems.
The control system 300 may be a computing system that includes a processing system 310, memory system 320, and input/output (I/O) system 330 for communicating with other devices, such as input devices 299 (e.g., fill level sensors) and output devices 301 (e.g., powered devices 110 and/or valves), either of which may also or alternatively be stored in a cloud 302. The processing system 310 loads and executes an executable program 322 from the memory system 320, accesses data 324 stored within the memory system 320, and directs the system 40 to operate as described in further detail below.
The processing system 310 may be implemented as a single microprocessor or other circuitry, or be distributed across multiple processing devices or sub-systems that cooperate to execute the executable program 322 from the memory system 320. Non-limiting examples of the processing system include general purpose central processing units, application specific processors, and logic devices.
The memory system 320 may comprise any storage media readable by the processing system 310 and capable of storing the executable program 322 and/or data 324 (including thresholds for controlling the moisture management system, for example). The memory system 320 may be implemented as a single storage device, or be distributed across multiple storage devices or sub-systems that cooperate to store computer readable instructions, data structures, program modules, or other data. The memory system 320 may include volatile and/or non-volatile systems, and may include removable and/or non-removable media implemented in any method or technology for storage of information. The storage media may include non-transitory and/or transitory storage media, including random access memory, read only memory, magnetic discs, optical discs, flash memory, virtual memory, and non-virtual memory, magnetic storage devices, or any other medium which can be used to store information and be accessed by an instruction execution system, for example.
Accordingly, the systems and methods described above eliminate the manual draining of water traps, while also providing for the collection of moisture within the medical device 2, condensing the water back into the room to directly eliminate the risk of water on the floor and/or bacterial growth within the medical device 2. This also prevents water from getting into the breathing system, including by the embodiment of
In certain embodiments, moisture detectors 160, 170 are also provided, as shown in
The functional block diagrams, operational sequences, and flow diagrams provided in the Figures are representative of exemplary architectures, environments, and methodologies for performing novel aspects of the disclosure. While, for purposes of simplicity of explanation, the methodologies included herein may be in the form of a functional diagram, operational sequence, or flow diagram, and may be described as a series of acts, it is to be understood and appreciated that the methodologies are not limited by the order of acts, as some acts may, in accordance therewith, occur in a different order and/or concurrently with other acts from that shown and described herein. For example, those skilled in the art will understand and appreciate that a methodology can alternatively be represented as a series of interrelated states or events, such as in a state diagram. Moreover, not all acts illustrated in a methodology may be required for a novel implementation.
This written description uses examples to disclose the invention, including the best mode, and also to enable any person skilled in the art to make and use the invention. Certain terms have been used for brevity, clarity, and understanding. No unnecessary limitations are to be inferred therefrom beyond the requirement of the prior art because such terms are used for descriptive purposes only and are intended to be broadly construed. The patentable scope of the invention is defined by the claims and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they have features or structural elements that do not differ from the literal language of the claims, or if they include equivalent features or structural elements with insubstantial differences from the literal languages of the claims.