 DISCHARGE ARM FOR SURGICAL SMOKE EVACUATION SYSTEM, SURGICAL SMOKE EVACUATION SYSTEM, APPLIANCE FOR
专利摘要:
utility model patent: "improvement related to systems for laparoscopic surgery". the invention relates to a surgical smoke evacuation system for use in removing gases and smoke created in surgical procedures from within an inflated surgical cavity. such a system comprises a discharge assembly to form a gas path, and which has an end which in use is located within said surgical cavity so that gases and / or surgical smoke within said cavity can pass out of said cavity cavity and through said discharge assembly along said gas path, a flexible discharge arm that has an end of operating location and an outlet end, and a self-supporting wall that defines a gas flow passage between said end of operational site and said outlet end, in use said open operational site end connected to said discharge set so that said surgical gases and / or smoke can pass out of said discharge set and into said discharge arm, a filter connected in use at the outlet end of the discharge arm, at least part of said discharge arm wall formed of a breathing material This breathable material allows water vapor to pass through the discharge arm wall without allowing liquid water or surgical smoke or other gases to pass through. 公开号:BR112012015601B1 申请号:R112012015601-2 申请日:2010-12-20 公开日:2020-07-14 发明作者:Michael Joseph Blackhurst;James Alexander Gordon;Jonathan David Harwood;David John Bain 申请人:Fisher & Paykel Healthcare Limited; IPC主号:
专利说明:
FIELD OF THE INVENTION [0001] The invention deals with smoke insufflation and evacuation systems for laparoscopic or electrosurgical or electrocauterization procedures. BACKGROUND OF THE INVENTION [0002] Laparoscopic surgery - minimally invasive surgery (MIS) or “keyhole” surgery - is a modern technique in which operations on the abdomen are performed by small incisions (usually 0.5-1.5 cm) if compared with the largest incisions in traditional procedures. Laparoscopic surgery includes operations within the abdominal or pelvic cavities. In abdominal surgery, for example, the abdomen is usually inflated with carbon dioxide gas to create a working and viewing space. The abdomen is swollen like a balloon (inflated); elevating the abdominal wall above the internal organs like a dome. The gas used is usually CO2, common to the human body, which can be absorbed by the tissue and removed by the respiratory system. It is also non-flammable, which is important, as electrosurgical devices are commonly used in laparoscopic procedures. Figure 1 is a diagram of a typical procedure, with part of the outer layers of the body not shown in order to show the interior details. [0003] The purpose of insufflation is to create a workspace within the body to perform surgical procedures which can often involve electrosurgery or electrocauterization. Lasers are also becoming increasingly popular in modern surgical procedures. The use of these devices tend to create surgical smoke within the workspace due to the burning of tissue. Smoke evacuation systems using a discharge arm are commonly used to remove smoke from the operating room, so that a surgeon can see what he or she is doing, and so that this potentially harmful material does not remain. inside the body cavity after surgery. One end of the discharge arm is connected to, or inserted into, a second incision (or sometimes the same incision). A typical smoke evacuation system usually includes a trocar and cannula at the end to assist insertion into the operative site. The smoke exits the inflated abdominal area through the discharge arm. The discharge arm may be attached to the end of a laparoscopic instrument in order to provide evacuation close to the location where electrocauterization takes place. Usually, gases and smoke from the body cavity are filtered through a filter to remove particulate matter before they are vented into the atmosphere. The filter can also be additionally designed to remove chemicals and any harmful microorganisms from surgical smoke. US 5,578,000, US 6,110,259 and US 5,226,939 all describe examples of surgical smoke evacuation systems. Commonly available surgical smoke evacuation systems include, for example, the SmartVac® smoke evacuation system and the SeeClear® MAX smoke evacuation system. The smoke filter is usually located at the other end of the discharge arm of that end which is inserted into the incision. [0004] Commonly, a vacuum source is connected to the other end of the discharge arm - the end furthest from the patient. The vacuum source can be a wall-mounted vacuum or an independent vacuum device. The vacuum creates a negative pressure within the operating location to 'suck in' smoke and any excess blowing gases. In a layout where a vacuum source is used, it is usual to position the filter at a point along the duct, usually just upstream of the vacuum source to remove unwanted contaminants from the evacuated smoke. [0005] Current smoke evacuation systems use a plastic pipe (usually a PVC pipe), for the discharge arm. The atmosphere within the patient's abdominal cavity is generally moist, and the heat from surgical operations such as electrocautery tends to increase humidity as the heat causes moisture to evaporate from the patient's internal organs. It has been a common practice in laparoscopic surgery to use dry gases. However, it is also desirable for CO2 or another insufflation gas to be humidified in a manner similar to how the gases are humidified for respiratory therapy - for example, CPAP or similar. In insufflation applications, the gases are humidified before they are passed into the abdominal cavity. This can help prevent 'drying' of the patient's internal organs, and can decrease the amount of time required for recovery from surgery. [0006] Smoke evacuation systems are commonly used with insufflation systems. Insufflation systems deliver humidified gases into an incision to create a workspace within the body for electrocautery surgery, electrosurgery or laparoscopic procedures. Insufflation systems generally comprise humidifying chambers that contain a quantity of water inside them. The humidifier usually includes a heater plate that heats the water to create water vapor that is transmitted into the incoming gases to humidify the gases. The gases are transported out of the humidifier with water vapor. The humidification chamber requires a minimum level of water to allow the humidification chamber to properly humidify incoming gases. [0007] Consequently, a health professional a person using the insufflation system needs to be checking the water level inside the humidification chamber and adding more water when required. This job can be tedious and is often overlooked. US 6802314 describes a method for monitoring the water level within a humidification chamber. The method is implemented in an electronic controller that controls the operation of the humidifier heater plate and the operation of the fan used with the humidifier. The method involves monitoring the temperature of the heater base 102, the temperature of the humidification chamber 103 (or chamber outlet temperature) and the energy requirement of the heater base (the amount of energy being supplied to the heater base) ). Thermal conductivity is calculated using the measured values. Thermal conductivity is calculated by the heater base energy requirement divided by the heater plate temperature minus the chamber temperature. [0008] The controller compares the calculated thermal conductivity value with a predetermined limit value which can be experimentally determined at various gas flow rates. The predetermined limit values can be stored in a ROM and be accessible to the controller so that the controller would simply determine the present flow rate of the gases, calculate the thermal conductivity value, access the table in the ROM based on the present flow rate and read the associated predetermined threshold value. If the calculated thermal conductivity is greater than the thermal conductivity value then the controller would wait for a predetermined time before issuing an alarm so that the water level could be completed without any loss of moisture in the gas flow. [0009] It is an object of the present invention to at least partially help to overcome these problems and other defects in the prior art, or at least provide the public with a useful alternative. [00010] The term "comprising" as used in this specification means "consisting at least in part of". When interpreting each statement in this specification that includes the term "comprising", features other than that or those prefaced by the term may also be present. Relative terms such as "understand" and "understand" must be interpreted in the same way. [00011] In this specification where reference was made to patent specifications, other external documents, or other sources of information, this is generally for the purpose of providing a context for discussing the characteristics of the invention. Unless otherwise specifically stated, reference to such external documents should not be regarded as an admission that such documents, or such sources of information, in any jurisdiction, are prior art, or form part of a common general knowledge in the art. . SUMMARY OF THE INVENTION [00012] In a first aspect, the invention can generally be said to consist of a surgical smoke evacuation system for use in removing gases and smoke created in surgical procedures from within an inflated surgical cavity, said cavity of the type that has at least one opening adapted for gas discharge, said surgical smoke evacuation system comprising: a discharge assembly adapted to form a gas path, and which has an end which in use is located within said surgical cavity so that gases and / or surgical smoke within said cavity can pass out of said cavity through said discharge assembly along said gas path, a flexible discharge arm that has an operating site end and an outlet end , and a self-supporting wall that defines a gas flow passage between said end of the operational site and said exit end, in u only said end of the open operating site is sealingly connected to said discharge set so that said gases and / or surgical smoke can pass out of said discharge set and into said discharge arm, a filter in use connected to the outlet end of the discharge arm, at least a part of said discharge arm wall formed of a breathable material, said breathable material allowing water vapor to pass through the discharge arm wall without allowing liquid water to pass through or surgical smoke or other gases. [00013] Preferably, said breathable material comprises at least 10% of said wall of said discharge arm surface area. [00014] Preferably, said wall has an internal diameter between 10 mm and 25 mm. [00015] Preferably, said discharge arm is between 400 mm and 1500 mm in length. [00016] More preferably, said discharge arm is 470 mm long. [00017] Preferably, said smoke evacuation system is a passive smoke evacuation system, said pressurized surgical cavity due to insufflation gas being pumped into said surgical cavity from a pressurized gas source so that the said conduit has a higher pressure at the end of the operating location than at said outlet end, said outlet opening downstream open to the atmosphere. [00018] Preferably, said breathable material is a hydrophilic thermoplastic. [00019] Alternatively, said breathable material is a perfluorinated polymer. [00020] As an additional alternative, said breathable material is made of treated braided fabric. [00021] Preferably, said smoke evacuation system further comprises a support for receiving and retaining said discharge arm in such a way that said arm is folded along its length where said arm is attached to said support, said fold in said arm formed so that in use said filter is not the lowest point of the arm, said lower part of the fold being the lowest part of the arm. [00022] Preferably, said support has at least one and preferably two reception characteristics for receiving and retaining said discharge arm, said reception characteristic or characteristics arranged in a relative manner to each other to create a fold in U within said arm when the arm is housed within said feature or features. [00023] Preferably, said U-fold behaves substantially like a water trap so that any condensation of liquid within said discharge arm flows towards the fold in one and accumulates near the lowest point of said fold in U. [00024] Preferably, said reception characteristics are slits or rings and said arm mounts within said slits or rings. [00025] Preferably, said support is substantially U-shaped. [00026] Preferably, said reception characteristics are positioned at or near the opposite ends of said support. [00027] Preferably, in use, said support maintains at least two points of contact with the ground to form a stable structure for retaining and securing said arm. [00028] In a further aspect of the support, said support still comprises at least two legs extending from said support, said legs contacting the ground and supporting said support in an upright position. [00029] Preferably, said legs of said support provide two of three said points of contact with the ground, and at least part of the body of said support providing the third of said three points of contact with the ground. [00030] Preferably, said support includes an additional support member, said support member and said legs forming three points of contact with the ground. [00031] Preferably, wherein said support includes at least one stabilizing mass within the support or attached to the support, said stabilizing mass stabilizing the support so that said support and the arm remain in correct orientation in use. [00032] Preferably, said stabilizing mass is a moving mass. [00033] Alternatively, said stabilizing mass is a stationary mass. [00034] Preferably, said stabilizing mass is made of a rigid material, said material being more dense than said support. [00035] Preferably, said support is formed of a rigid material. [00036] More preferably, wherein said support is formed of molded plastic. [00037] In a further alternative aspect, said system includes a retaining member that engages with said smoke evacuation arm, said retaining member adapted to bend or twist said arm so that in use said filter is not the lowest point on the arm. [00038] Preferably, said retaining member is attached to said filter at one end of said retaining member, an opposite end of said retaining member including a retaining feature adapted to receive and retain said arm upstream of said filter so that said arm is folded or contorted so that said filter is not the lowest point of said arm. [00039] Preferably, said arm is bent or contorted to form a U-fold in use, said U-fold acting as a siphon so that any condensation or liquid within said arm flows towards said U-fold. and accumulate near the lowest point of said U-fold. [00040] Preferably, said retaining feature is a hook or loop, said hook or loop adapted to receive and retain said arm so that said arm upstream of said filter is folded or contorted. [00041] Alternatively, wherein said holding feature is a clip, said clip adapted to receive and retain said arm so that said arm upstream of said filter is bent or contorted. [00042] In an additional preferable aspect, said breathable material forms a flow path for water vapor from the interior of said discharge arm to the ambient air, so that said water vapor can pass from inside the air arm. discharge into ambient air through the breathable material that forms at least part of said wall of said discharge arm. [00043] Alternatively, said water vapor is absorbed by the breathable material inside said discharge arm, said absorbed water passing through said wall of said discharge arm into the atmosphere, said breathable material preventing the water condensate. and the particulate matter pass through said wall. [00044] Preferably, said wall of said discharge arm comprises multiple regions of said breathable material. [00045] Alternatively, said regions of breathable material are elongated and run for at least a substantial length of said discharge arm. [00046] Preferably, said regions of breathable material are spaced along the length of said discharge arm. [00047] Preferably, said regions of breathable material are formed as elongated strips along the wall of said discharge arm. [00048] In a second aspect the invention can be said to consist generally of a surgical smoke evacuation system for use in removing gases and smoke created in surgical procedures from within an inflated cavity, said cavity of the type that has at least an opening adapted for gas discharge, said surgical smoke evacuation system comprising: a discharge set adapted to form a gas path, and which has an end which in use is located within the surgical cavity so that the gases and / or surgical smoke within the cavity can pass out of the cavity and through said discharge set along said gas path, a flexible discharge arm that has an end of operating location and an outlet end, and a wall self-supporting which defines a gas flow path between the end of the operating site and the end of the outlet, in use the end of the operating site al sealingly connected to the discharge assembly so that gases and / or surgical smoke can pass out of the discharge assembly and into the discharge arm, a filter in use connected to the outlet end of the discharge arm, an adapted support to receive and retain said discharge arm in such a way that said arm is folded along part of the length of the discharge arm where the support contacts the arms, so that in use the fold along part of said length the discharge arm acts to collect any condensation formed within the discharge arm, said arm being folded so that in use said filter is not the lowest point of said arm. [00049] Preferably, said fold in said discharge arm is substantially a U-shaped fold, said U-shaped fold acting as a condensation collection point to collect any condensation formed within said discharge arm, said U-fold also preventing said condensation from flowing along the arm to the filter or the arm outlet. [00050] Preferably, said support has two reception characteristics for receiving and retaining said arm. [00051] Preferably, said reception characteristics are slits or rings adapted so that said arm fits by means of said slits or rings. [00052] Preferably, said support is substantially U-shaped and includes a channel for receiving and retaining said arm within said support. [00053] Preferably, said reception characteristics are positioned at opposite ends of said support. [00054] Preferably, said support includes a stabilizing mass attached to or housed within said support, said stabilizing mass stabilizing said support so that said support remains in the correct orientation when in use. [00055] In an alternative form of the support said support is a retaining member extending from said filter, said retaining member coupling with said arm, said arm being bent or contorted by said retaining member, so that said filter is not the lowest point of said arm. [00056] Preferably, said holding member includes a holding feature that receives and holds said arm, said holding feature by folding said arm so that said filter is not the lowest point of said arm. [00057] Preferably, wherein said holding feature is a hook or loop. [00058] In a further aspect of the support said support comprises a body having a first end and a second end, said first end is connected to said outlet end of said discharge arm, said second end of said support in said filter, said support forming a sealed gas path to allow the flow of gases and / or smoke from the outlet end of the discharge arm to the filter, the gases and / or smoke moving through said support. [00059] Alternatively, said support comprises a body having a first end and a second end, said first end connecting at the outlet end of said discharge arm, said second end of said support connecting to a substantially flexible secondary conduit said filter connected to said secondary conduit, said support forming a sealed gas path to allow the flow of gases and / or smoke from the outlet end of said discharge arm to said secondary conduit, said gases and / or smoke moving through said support. [00060] Preferably, said first and second ends of said support comprise threaded connections for connecting the first end to said discharge arm and connecting the second end of the support or to said filter or said secondary duct. [00061] Alternatively, said first and second ends of said support include couplers. [00062] Preferably, said support maintains at least two points of contact with the ground to form a stable structure to retain and secure said smoke evacuation arm. [00063] Preferably, said support includes at least two legs extending from said support, said legs in use contacting the ground and supporting said support in an upright position. [00064] Preferably, said legs of said support provide two of three points of contact with the ground and the body of said support provides the third of said three points of contact with the ground. [00065] Preferably, said support is formed of a rigid material. [00066] Preferably, said support is formed of molded plastic. [00067] In an additional alternative aspect, at least part of said support is formed of a breathable material, said breathable material allowing the passage of water vapor through said support to the ambient air without allowing the passage of said liquid water or of surgical smoke. [00068] As an additional alternative aspect, the entire support is formed of a breathable material. [00069] In an additional aspect, at least part of said secondary duct is formed of a breathable material so that said breathable material allows water vapor to pass out of said secondary duct into the ambient air without allowing the passage of liquid water or surgical smoke or other gases. [00070] Preferably, at least part of the wall of said discharge arm is formed of a breathable material, said breathable material allowing the passage of water vapor through the wall of the discharge arm without allowing the passage of liquid or water. surgical smoke or other gases. [00071] More preferably, said breathable material comprises at least 10% of said wall of said discharge arm surface area. [00072] Preferably, said wall has an internal diameter between 10 mm and 25 mm. [00073] Preferably, said discharge arm is between 400 mm and 1500 mm in length. [00074] More preferably, said discharge arm is 470 mm long. [00075] Preferably, said smoke evacuation system is a passive smoke evacuation system, said pressurized surgical cavity due to insufflation of gas being pumped into said surgical cavity from a pressurized gas source so that the said conduit has a higher pressure at the end of the operating location than at said outlet end, said outlet opening downstream open to the atmosphere. [00076] In one form, said breathable material is a hydrophilic thermoplastic. [00077] In an alternative form, said breathable material is a perfluorinated polymer. [00078] In an additional alternative form, said breathable material is made of treated braided fabric. [00079] Preferably, the surface area of said discharge arm is between 12560 mm2 and 47100 mm2. [00080] Preferably, said system further comprises an additional conduit arranged coaxially with said discharge arm, said additional conduit arranged around the outside of said discharge arm to cover said discharge arm, said additional conduit acting like an air jacket, in use said water vapor passing through the breathable material of said discharge arm into the air in said conduit, said conduit carrying water vapor away from said breathable areas of said discharge arm. [00081] In a third aspect the invention can generally be said to consist of an insufflation system, which comprises: a gas source, a humidification chamber adapted to contain a volume of water that has an inlet and an outlet, said inlet of said humidification chamber in gas communication with said gas source to receive gases from said gas source, said gases entering through said inlet and passing through said outlet of said humidification chamber, a conduit that has a first end and second end, said first end connected to said outlet of said humidification chamber, said first end of said gas communication conduit with said humidification chamber outlet and receiving said humidified gases from said humidifier, said second end of said conduit communicating with a surgical site and providing said humidified gases to said surgical site, a heater base provided adjacent to said humidification chamber, said heater base providing heat for said amount of water within said humidification chamber in order to provide water vapor for said gases flowing through said humidification chamber, a first sensor of temperature trapped in said heater base and monitoring the temperature of said heater base, a second temperature sensor attached adjacent to said outlet of said humidification chamber, said second temperature sensor monitoring said temperature of said humidification chamber, a controller adapted to control the heat provided by said heater base for said humidification chamber, said controller connected to said first and second temperature sensors and receiving the temperature information from said sensors. [00082] Preferably, said controller implements a method for determining a low or no water condition in said humidification chamber, said method comprising the steps of: measuring the temperature of gases leaving the chamber, measuring the energy supplied for a heater base, measure the rate of gas flow through the chamber, determine a low or no water condition when the temperature of the gases leaving the chamber is decreasing, the energy supplied to said heater base is constant or increasing and the rate of gas flow through said chamber is unchanged, for at least two minutes. [00083] In one form, said system includes a bell, the operation of said bell controlled by said controller when said low or no water condition is detected. [00084] Preferably, said controller turns off the power to said heater base when a low or no water condition is detected. [00085] In a fourth aspect the invention can generally be said to consist of a method for determining a low or no water condition in a humidification chamber, said humidification chamber part of an insufflation apparatus to provide insufflation gases humidified to a surgical site or peritoneal cavity of a patient to inflate said cavity to said surgical site, said method comprising the steps of: measuring the energy supplied to a heater base, measuring the temperature of gases leaving said chamber humidification, measure the rate of gas flow through said humidification chamber, determine a low or no water condition based on a temperature in reduction of gases leaving said humidification chamber, while said energy for said heater it is constant or increasing and the flow of gases through said chamber is constant for a predetermined time. [00086] Preferably, said method includes the step of: said predetermined time is at least two minutes, said controller turning off the power to said heater base if a low or no water condition is measured. [00087] Preferably, said method comprises an additional step of alerting a user when a low or no water condition is detected. [00088] Preferably, said condition of low water or no water is determined if said temperature of gases leaving said chamber reduces while said energy for said heater base increases by at least two minutes. [00089] Preferably, said filter includes an adjustable outlet port connected to said filter, said outlet port allowing a user to adjust the amount of gases flowing out of said filter. [00090] In a fifth aspect the invention can generally be said to consist of a discharge arm for use in a surgical smoke evacuation system to evacuate surgical smoke and gases from a surgical site within or on a patient, said discharge arm comprising: a flexible elongated hollow body that defines a gas transport path to transport the smoke and gases created in surgical procedures, said body having an operative site end adapted for connection to the surgical site, an outlet end adapted to connect to a filter, said surgical smoke and gases substantially moving said surgical site to said filter through said elongated hollow body, the elongated hollow body being at least partially constructed of a breathable material or region that allows the passage of vapor from water out of the elongated hollow body through the region or breathable material while restricting the passage of liquid water or surgical smoke and gases. [00091] Preferably, said water vapor is passed from the elongated body to the ambient air through the region or breathable material. [00092] Preferably, said arm also includes an air jacket arranged coaxially with said elongated hollow body, said air jacket covering and closing said elongated hollow body, said water vapor passing through the region or breathable material into said air jacket. [00093] Preferably, said air jacket is formed by an additional conduit arranged coaxially with said elongated hollow body. [00094] Preferably, said breathable material comprises at least 10% of the surface area of said discharge arm. [00095] Preferably, said discharge arm has an internal diameter between 10 mm and 25 mm. [00096] Preferably, said discharge arm is between 400 mm and 1500 mm in length. [00097] More preferably, said discharge arm is 470 mm long. [00098] Preferably, said discharge arm has a higher pressure at the end of the operating site adapted to connect to a surgical site and a lower pressure at the outlet end adapted to connect to the filter, said pressure differential causing said surgical smoke and gases move from said surgical site to said filter through said elongated hollow body. [00099] In one form, said breathable material is a hydrophilic thermoplastic. [000100] Alternatively, said breathable material is a perfluorinated polymer. [000101] Alternatively, said breathable material is made of treated braided fabric. [000102] Preferably, the arm further comprises: a support, said arm attaching to said support, said support adapted to keep said discharge arm in use in such a way that said arm is folded along its length where said arm attaches to said support, said fold of said arm is formed in such a way that said filter is not the lowest point of the arm, said lower part of the fold being the lower part of the arm. [000103] Preferably, said support includes at least one, but preferably two reception characteristics for receiving and retaining said discharge arm, said reception characteristic or characteristics arranged in a relative manner to each other to create a fold U-shaped inside said arm when the arm is placed within said feature or features. [000104] Preferably, said U-fold behaves substantially like a water siphon so that any condensation of liquid within said smoke evacuation arm flows towards the U-fold and accumulates near the lowest point of said U-fold. [000105] Preferably, said support maintains at least two points of contact with the ground to form a stable structure to retain and secure said arm. [000106] Preferably, said support includes at least two legs extending from said support, in use said legs contacting the ground and supporting said support in an upright position. [000107] More preferably, in use, said legs of said support provide two of three said points of contact with the ground, and the body of said support providing the third of said three points of contact with the ground. [000108] Preferably, said support includes an additional support member, said support member and said legs in use forming three points of contact with the ground. [000109] Preferably, said support includes at least one stabilizing mass within the support or attached to the support, said stabilizing mass stabilizing the support so that said support and the arm remain in a correct orientation. [000110] Preferably, said stabilizing mass is a mobile mass. [000111] Alternatively, said stabilizing mass is a stationary mass. [000112] Preferably, said stabilizing mass is made of a rigid material, said material being more dense than said support. [000113] Preferably, said support is formed of a rigid material. [000114] More preferably, said support is formed of molded plastic. [000115] In a further aspect, said support is a retaining member extending from said filter, said retaining member coupling with said arm, said arm being folded or twisted by said retaining member so that in use said filter is not the lowest point of said arm. [000116] Preferably, said holding member includes a holding feature that receives and holds said arm, said holding feature by folding said arm so that said filter is not the lowest point of said arm in use . [000117] Preferably, said retention characteristic is a hook or loop. [000118] Preferably, said arm is adapted to connect to a surgical site through a discharge set adapted to form a gas path, said discharge set having an end which in use is located within said surgical site so that gases and / or surgical smoke within the cavity can pass out of said cavity through said discharge assembly along the gas path into the discharge arm. [000119] Preferably, said discharge arm includes a first connector on said operating side end of said arm and a second connector on said outlet end of said arm. [000120] Preferably, said first connector is a luer lock connector, said first connector adapted to connect to said discharge arm, said second connector being a barbed connector adapted to connect to said filter. [000121] In a sixth aspect the invention can generally be said to consist of a kit of parts for a disassembled surgical smoke evacuation system for use in removing gases and smoke created in surgical procedures from within an inflated cavity, said kit for a disassembled surgical smoke evacuation system comprising: a flexible discharge arm having an operating site end and an outlet end, said arm being an elongated hollow body, said hollow defining a gas transport path, said hollow body or at least a part of said hollow body formed of a breathable material, said breathable material allowing the passage of water vapor but not liquid water through said hollow body, a double-ended filter, one end of the pluggable filter at the outlet end of said discharge arm, a discharge assembly having an end which can be located within a surgical cavity and another connectable end at said operational end of said arm, said discharge assembly adapted to form a gas path between the two ends of said discharge arm, said flexible discharge arm, said filter and said assembly flue connecting together to form said surgical smoke evacuation system. [000122] Preferably, said kit further comprises: a support, said support including at least one receiving feature, and at least two legs extending from said support, said receiving feature capable of receiving and retaining said arm within it when said kit is assembled and said arm is coupled with said receiving feature said arm is folded so that said filter is not the lowest point. [000123] Preferably, said kit further comprises: a holding member attached to said filter, said holding member being an elongated member, said holding member including a holding feature at one end of said holding member, said retaining feature connectable with said arm in use so that in use said arm is folded so that said filter is not the lowest point. [000124] The terms smoke evacuation arm and discharge arm are used interchangeably and refer to the same physical characteristic. [000125] This invention may also be said to generally consist of the parts, elements and characteristics referred to or indicated in the order specification, individually or collectively, and any or all combinations of any two or more of said parts, elements or characteristics, and where specific integers are mentioned herein which have equivalents known in the art to which the invention refers, such known equivalents are considered to be incorporated herein as if individually presented. [000126] As used herein the term "and / or" means "and" or "or", or both. As used "(s)" after or noun means the plural and / or singular forms of nouns. BRIEF DESCRIPTION OF THE FIGURES [000127] Figure 1 shows a diagram of a typical laparoscopic procedure, with part of the outer layers of the body not shown in order to show the interior detail. [000128] Figure 2 shows a laparoscopic humidification system in use with a patient receiving the humidified gases from the system, and a discharge arm according to the present invention carrying these gases out of the surgical site. [000129] Figure 3 shows a detailed view of the smoke evacuation system in figure 2. [000130] Figure 4 shows the patient model used to test the efficiency of a breathable discharge arm used with the smoke evacuation system. [000131] Figure 5 shows a weighing and configuration scale to measure the weight of the smoke evacuation system. [000132] Figure 6 shows an operating position of the smoke evacuation system when in use with the patient model shown in figure 4. [000133] Figure 7 shows the test configuration used to test the efficiency of a breathable discharge arm used with the smoke evacuation system. The figure shows an inflation system and the smoke evacuation system used with the patient model in figure 4. [000134] Figure 8a shows an outlet tube attached to the filter of the smoke evacuation system, the outlet tube being made of a breathable material. [000135] Figure 8b shows an outlet tube attached to the filter of the smoke evacuation system, the outlet tube being made of a non-breathable material. [000136] Figure 9 shows a support for receiving and retaining the smoke evacuation arm, the support having two legs and a support member extending from the support body. [000137] Figure 10 shows another form of the support that has two legs, one leg being substantially larger than the other and that provides a stable base for the support. [000138] Figure 11 shows an additional form of the support that has no legs, only a body to receive and retain the arm. [000139] Figure 12 shows an additional form of the support, the support being a retaining member that extends from the filter with a retaining feature at one end of the retaining member to receive and secure the arm. DETAILED DESCRIPTION SYSTEM OVERVIEW [000140] The preferred embodiments of the present invention will now be described in detail with reference to the figures. [000141] Figure 2 and figure 7 show a typical inflation system 100 as could be used with the present invention. The insufflation system supplies the insufflation gases to a patient 1. The insufflation system 100 includes an insufflator 101 that humidifies a flow of gases supplied by a source of gases 107. Humidified insufflation gases are supplied at a pressure above the pressure atmospheric, into the patient's abdominal or peritoneal cavity. The insufflator 101 includes a heater base 102 and a humidifier chamber 103, with the chamber 103 in use in contact with the heater base 102 so that the heater base provides heat to the chamber. The insufflation gases are passed through the chamber 103 so that they become humidified to an appropriate level of humidity. The system includes a delivery conduit 105 that connects between the humidification chamber 103 and the peritoneal cavity or surgical site. The conduit has a first end and a second end, the first end being connected at the outlet of the humidification chamber 103 and receiving the humidified gases from the chamber 103. The second end of the conduit is placed within the surgical site or peritoneal cavity and the humidified insufflations move from chamber 103, through the conduit and into the surgical site to inflate and expand the surgical site or peritoneal cavity. The system also includes a controller 104 that regulates the amount of moisture supplied to the gases by controlling the energy supplied to the heater base 102. The controller can also be used to monitor the water inside the humidification chamber and determine a low water condition. or without water, which will be described later. A smoke evacuation system 300 is shown leading out of the patient's body cavity. This will be described in detail below. [000142] Typically, the insufflator pressure will be adjusted between 9 mm / Hg and 15 mm / Hg depending on the size of the patient and the amount of insufflation required. The flow rate of the insufflator is adjusted between 1 L / min and 5 L / min depending on the requirements of the specific operation. In the most preferred form, carbon dioxide is used as the insufflation gas. [000143] Figure 3 and figure 6 show a more detailed view of the smoke evacuation system 300 of the present invention. The smoke evacuation system can be used in conjunction with the inflation system 100 described above or can be used with other suitable inflation systems. The smoke evacuation system 300 comprises a discharge arm 301, a discharge assembly 302 and a filter 303. The discharge arm 301 connects between the filter 303 and the discharge assembly 302, which in use is located inside the or adjacent to the operative site (the peritoneal cavity, for example, as indicated by item C in figure 1). Preferably the discharge arm 301 is a self-supporting duct or tube (the duct is capable of supporting its own weight without collapsing) with two open ends: an operating site end and an outlet end. The discharge arm in figure 3 is shown with a dashed line to show that it is long and the length can be variable. The term discharge arm and smoke evacuation arm are used interchangeably in this specification, both terms referring to the same characteristic. Preferably, the peeling arm includes a first connector 310 at the end of the operating location and a second connector 311 at the outlet end. [000144] In the preferred embodiment, the operating site end includes or is adapted for connection to the discharge assembly 302, which comprises a luer cone 302a and a cannula orifice 302b. The first connector 310 allows the connection of the operating site end to the discharge assembly 302. The first connector is any suitable connector, more preferably a luer lock connector. The luer cone 302a allows the end of the operating site to be connected to the cannula orifice 302b. In use, an open end or part of the cannula orifice 302b is placed or located within the surgical cavity, such as that indicated by item C in figure 1 (i.e., the operative site) through a small incision or the like. Preferably the cannula orifice 302b is 5.5 mm in diameter. It is more preferred that cannula orifice 302b includes a valve 304 that can be opened or closed to act as an on / off valve. Any other movable obstruction can be used as an alternative to valve 304. With the cannula orifice open, the discharge arm 301 is open to the surgical cavity and the surgical smoke created within the surgical cavity can flow into the discharge arm. 301. With the cannula orifice in the closed position, the discharge arm 301 is sealed from the surgical cavity and no smoke or gas flows into the discharge arm 301. [000145] The discharge arm 301 has a filter unit 303 connected to the outlet end. The second connector 311 allows the outlet end of the discharge arm to connect to the filter through a suitable connection. The second connector is any suitable connector, most preferably a barbed connector. The filter unit 303 comprises a hard wrap, which surrounds a filter medium and holds the filter medium in position. The filter unit has two ends or sides: one end or upstream side, connected to the outlet end of the discharge arm 301, and one end or downstream side that either opens to the atmosphere, or is adapted for use in connection. to a vacuum source. In the preferred embodiment, the side or end downstream of the filter opens to the atmosphere. The filter unit body 303 also defines a gas flow path between the upstream side and the downstream side so that surgical smoke and other gases in use pass through the filter unit 303, and through the filter medium inside the filter unit. The filter medium comprises a filter material or other filter medium that is adapted to filter the gases that pass through the filter and leaves a residual (clean) gas. The preferred filter medium includes carbon or is made of UPLA grade hydrophobic glass microfiber (ultra-low particulate air). [000146] The filter medium is adapted to filter or trap as much of the contaminating material in the gas as possible. That is, particulate matter, odors and gaseous hydrocarbons are, as far as possible, removed from surgical smoke. The filter passes the residual gas that remains after the filtration process. In the preferred embodiment, the gas is passed into the atmosphere. The residual gas is almost 100% carbon dioxide. Preferably, the filter removes 99.999% of all particles, cells and viruses and has a retention of up to 0.02 microns. [000147] In the preferred embodiment described above, the smoke evacuation system 300 is a passive smoke evacuation system meaning that it does not require a vacuum source or any equivalent device to suck surgical smoke through the discharge arm 301 of the system. The mechanism for evacuating smoke through the discharge arm 301 will now be explained: the insufflation system is activated and the surgical site is pumped with carbon dioxide gas. The surgeon starts the surgical procedures once the surgical site is inflated to the correct level. Once the flow rates and temperatures of the inflation system have stabilized, the smoke evacuation system can be activated (by opening valve 304). The inflation system supplies the inflation gases at a positive pressure. [000148] The valve 304 as described above is opened to allow the gas to travel through the cannula orifice 302b and through the discharge arm 301. The smoke travels through the discharge arm 301, through the filter unit 303 and out through the outlet end. The smoke is "purified" by filter 303. Filter 303 retains particulate matter, viruses, odors, harmful fumes and other potentially harmful particles. In an alternative form, the filter may also include an adjustable outlet orifice in said filter. The orifice is an outlet orifice that allows the user to vary the flow of gases out of said filter. The adjustable outlet port can also function as an on / off switch for the smoke evacuation system. Since the smoke evacuation system is preferably a passive smoke evacuation system, adjusting the outlet orifice in the filter allows a user to adjust the amount of gases flowing into and out of the smoke evacuation system as required. For example, the user could close the exit orifice which would effectively "shut down" the smoke evacuation system by restricting the flow out of said filter, alternatively the user could open the orifice to allow gases to flow through the evacuation system. of smoke, thereby "turning on" the smoke evacuation system. [000149] Surgical smoke travels through the smoke evacuation system 300 due to the negative pressure gradient that exists. The outlet end of the smoke evacuation system is at a lower pressure compared to the pressure at the operating site. The operating site is pressurized due to the pressurized insufflation gases supplied into the operating site. The outlet end of the duct and filter is at atmospheric pressure which is significantly less than the pressure of the pressurized gases. This negative pressure gradient forces surgical smoke to flow through the exhaust arm 301 of the smoke evacuation system, through the filter 303 and out of the outlet end. UNLOADING ARM OF SMOKE EVACUATION SYSTEM [000150] The gases supplied by the insufflation system 100 can be humidified at the point of entry into the body cavity (that is, as indicated by item C in figure 1). Alternatively, the insufflation gases can be provided without any humidification. Since the body cavity is already wet and damp, gases do not tend to lose moisture inside the body, and can become fully saturated if they are no longer at the point of saturation. If the gases are dry at the entrance to the body cavity, they tend to become humidified as they pass through the body cavity, capturing the unity of the humid atmosphere within the body cavity above the internal organs. [000151] When these saturated gases pass out of the abdominal cavity, they pass along the cooler walls of the discharge arm, which is about one meter long or approximately. Moisture in gases tends to condense out of the gas over the walls of the discharge arm or flue. Water vapor can also condense on filter 303. The vapor that condenses on filter 303 and runs along the moisture discharge arm which has condensed on the walls can saturate filter 303 and cause it to become blocked. This potentially causes an increase in back pressure and impairs the system's ability to clear smoke. [000152] Condensed moisture inside filter 303 can cause the filter medium to become blocked, leading to an increase in back pressure and reduced filter efficiency 303 due to blocking. This is disadvantageous because the increased back pressure impairs the system's ability to effectively clean surgical smoke. Condensation inside the filter 303 can also at least partially block the filter medium and decrease the efficiency of the filter. Surgical smoke remaining at the operating site within the surgical cavity or within the discharge arm 301 of the evacuation system can be hazardous to the patient since the surgical smoke contains several potential toxins that can become entrained within the surgical cavity or the patient tissue. Surgeons' vision can be obstructed or impaired due to the surgical smoke remaining at the operating site and not being evacuated, potentially leading to a dangerous working environment for surgeons. Condensation can partially block the filter medium resulting in reduced filtration of toxins from surgical smoke. This could result in potentially harmful substances like odors, surgical smoke, dead cell matter and so on escaping into the theater. These types of materials can be hazardous to health and can lead to many health problems for medical professionals and the patient. [000153] Applicants performed tests which indicate that the use of a discharge arm 301 that has a breathable wall or the wall of the arm 301 which includes a breathable material can help to alleviate this problem. A certain amount of moisture from the exhaust gases passes through the duct wall before reaching a 303 filter, and therefore there is less moisture in the gas to condense out of the gas and block the 303 filter. [000154] In this context, 'breathable material' means a material that allows water vapor to pass through the arm into ambient air while substantially preventing the passage of liquid water, droplets or water condensate, or any other components of surgical smoke (particles, etc.) for ambient air. Ambient air in this context refers to air outside the smoke evacuation arm or discharge arm, and not necessarily only for atmospheric air. In the preferred form the water vapor moves from inside the duct to atmospheric air. In an alternative way instead of the duct discharging air into the atmosphere, the discharge arm can be arranged coaxially with another duct placed around the outside of the discharge arm. The external duct acts as an air jacket and the water vapor from the discharge arm can move from inside the discharge arm to outside the external duct. The external duct or air jacket can act to evacuate any water vapor transmitted from the discharge arm to the air inside the external duct. [000155] The purpose of the breathable discharge arm, or a discharge arm with a breathable region or regions, is to allow water vapor to pass through the discharge arm wall into the ambient air, away from expired gases and smoke which in use passes through the discharge arm. The breathable material allows water vapor to pass through the discharge arm wall into the ambient air without allowing liquid water, gases or surgical smoke to enter the ambient air. Materials can be breathable due to their composition, physical structure or a combination. The mechanisms for transmitting water vapor through these breathable materials are numerous and known in the art. The purpose of the breathable region or regions of the supply duct wall is to allow water vapor to pass through the gas path along specific or independent drain locations. This reduces the accumulation of condensation inside the breathing tube by drying the humidified breathing gases (transmitting the water vapor to the surrounding ambient air) during its flow through the discharge arm. An example of a material that could be used for the breathable regions of the discharge arm 301 is an activated perfluorinated polymer material. An example of this polymer material is marketed under the brand name NAFION ™ by DuPont Fluro Products of Fayetteville USA. [000156] Alternatively, the breathable regions of the conduit may be constructed of hydrophilic thermoplastics, treated woven fabric products that exhibit breathable characteristics or a hydrophilic polyester block copolymer formed in a homogeneous flat film. An example of such a film is sold to the user under the SYMPATEX ™ brand. An additional alternative to the breathable material is ARNITEL ™ or GORETEX ™. This has been shown to experimentally help to reduce the accumulation of condensation within the discharge arm. As a certain amount of water vapor from gases passing through the discharge arm diffuses into the atmosphere, there is less water vapor inside the duct itself, so there is less chance of the filter becoming blocked with condensate, for example. [000157] Ideally, the discharge arm 301 would be formed in such a way, and will have dimensions so that the wall will allow the passage of substantially all or at least a significant portion of the moisture in the gases before the gases reach the filter 303. In in a practical sense a complete drying of the gas is not obtainable. The flow rate of the gases is very high, and the amount of moisture in the gases is very high, to allow more than one proportion to pass through the wall. The aim is therefore to produce a discharge arm that will allow sufficient moisture to pass through the wall as possible, so that the filter will not clog during use and before it is replaced. The amount of moisture in the exhaust gases that pass through the discharge member will depend on a number of factors, such as the moisture in the gases provided to a user, the humidity generated by the individual user, the extent of the surgery and the type of surgery, if the discharge arm is connected to an external vacuum source, etc. All of these factors mean that the amount of moisture in the gas is highly variable. Applicants propose to form the discharge arm in such a way as to allow sufficient moisture to pass through the wall to keep the filter unobstructed and functioning effectively for the most commonly encountered surgical situations, and to keep the filter as unobstructed as possible until it is replaced during normal maintenance of the supply circuit. [000158] One factor that allows moisture to pass through the discharge arm wall is the surface area of the wall. The diameter of the discharge arm 301 and the length of the discharge arm 301, also affect the rate of vapor transfer through the wall, and these have a direct impact on the rate of gas flow within the discharge arm. Applicants performed tests using a single type of duct as the discharge arm and the test results positively indicate that a useful proportion of the water within the discharge arm will pass through the wall before reaching the filter, and that there is, therefore, a value of having the breathable discharge arm these test results are further discussed as Example 1. [000159] Based on these results, it is anticipated that smoke evacuation systems that have discharge arms with properties as outlined below will be beneficial and will provide surgical teams with a useful choice. Preferably, as much wall of the discharge arm 301 as possible is made of a breathable material, in order to increase the surface area available for the transfer of water vapor from within the discharge arm to the outside. [000160] Preferably the length of the discharge arm is at least 400-1500 mm. The discharge arm can come in two forms. One arm shape is long enough to contact the floor as it extends from the operating table. In another form the arm is not long enough to contact the floor. The arm is shorter than the height of the operating table on which a surgical procedure is taking place. [000161] Preferably the internal diameter of the discharge arm 301 is between 10 mm and 25 mm. [000162] Preferably the surface area of the discharge arm is between 12560 mm2 and 47100 mm2 or any other suitable value. [000163] Preferably at least 10% of the surface area of the arm wall comprises a breathable material. [000164] The discharge arm is also preferably substantially flexible. "Flexible" in terms of this context refers to the discharge arm being unable to support its own weight. Flexible also means that it is easily foldable without damage or permanent [000165] All of the above materials can be formed into thin films. A number of ways are described in the art for forming thin flat films or tapes on discharge arms. These include a helical winding. Alternatively, it is envisaged that the conduit could be formed of short, ring-shaped portions of material arranged and connected in series or end to end. All or some of these portions could be made of breathable material - for example, the breathable sections could alternate with the non-breathable sections. Any of the forming methods known in the art can be used to form the conduit of the present invention. The conduit could also use a reinforcement cord (non-breathable) helically wound around the conduit, or a longitudinal reinforcement column or cord, or similar. Annular reinforcement rings could also be located at intervals along the discharge arm. The conduit could also be formed of two tapes wrapped like a double helix, with one of the tapes being breathable, and the other non-breathable. DISCHARGE ARM SUPPORT [000166] The discharge arm 301 can be of any suitable length. In one form the discharge arm 301 can be long enough to contact the floor. In another form, the arm may not be long enough to contact the floor. Preferably the arm is between 400 mm and 600 mm in length, the most preferred length being 470 mm. In use the arm hangs down as it extends away from the surgical site. The filter is at the low point when the arm hangs down, as filter 303 is at the end of the arm. This can be problematic as the moisture accumulated inside the discharge arm runs down towards the filter trapped at the outlet of the discharge arm. This moisture can cause the filter to become clogged and reduce the efficiency of the smoke evacuation system. The problems of moisture accumulation and clogged filters were discussed above. [000167] The smoke evacuation system 300 preferably comprises a smoke evacuation arm support. Various forms of the support are shown in figures 3, 9, 10, 11 and 12. Support 320 supports the smoke evacuation arm so that the filter is directed away from the ground. The support 320 holds the arm 301 in such a way that a U-fold is formed on the arm. Preferably, a section of the smoke evacuation arm is bent to stop the condensation flowing towards the filter 303, for example, by placing it on the support 320 in order to direct the filter away from the ground. The U-fold acts as a siphon for any condensation or moisture accumulated inside the arm and any condensation formed accumulates within the trough formed by the U-fold. The U-fold is seen in figures 9,10,11, and 12. [000168] Figure 3 shows the preferred location of the support in relation to the other elements of the smoke evacuation system. The support is preferably located near the outlet end of the discharge arm, closer to the filter than the patient. Alternatively, the support can be located at any point along the discharge arm. The support structure will be discussed in more detail with respect to figures 9 to 12. [000169] A form of the support may include legs secured extending from the support. The various forms of leg supports are shown in figures 9 and 10. Leg supports can be used when the discharge arm 301 is long enough to contact the ground. The preferred form of support with legs is shown in figure 9. Support 900 preferably can maintain at least three points of contact with the ground to provide maximum stability. The support 900 includes a body 901. The body 901 is preferably substantially curved to form a U-shape, as seen in figure 9. Alternatively, the body can be curved in any other shape that creates a U-shaped fold in the arm discharge before filter 303. Body 901 is preferably made of a substantially rigid material. The support 900 preferably includes at least two receiving characteristics 905. The receiving characteristics 905 receive and retain the discharge arm 301 in the correct orientation. The most preferred orientation is when the filter 303 is directed away from the ground. More preferably, the receiving characteristics are slits or rings, one at each end of the support 901. Alternatively, the receiving characteristics can be grooves or clips that can be opened and clipped to receive and retain the arm 301. The arm 301 preferably mounts by fitting within the receiving characteristics 905. The arm 301 can be easily removed from the support 900. The receiving characteristics 905 are preferably formed integral with the body 901. Alternatively, the receiving characteristics 905 can be separately formed and connected to the body by any appropriate fixation technique or mechanism. The body 901 of the support 900 preferably has a channel 906 formed within it. The channel 906 is formed to receive and retain the arm 301 within it. The support 900 can be formed of a plastic material. Alternatively, the support 900 can be formed of metal or any other suitable rigid material. In the preferred form the support 900 is formed under vacuum but can alternatively be formed from any other suitable material. [000170] The support can preferably comprise two legs 902, 903 extending from the body of the support. The legs act to support the support and allow the support to secure the arm. The two legs provide two of the points of contact with the ground. The support body 901 can include a support member 904 that acts as a third contact point. Preferably the support member is an elongated member as shown in figure 9. Alternatively, the support member 904 can have any other suitable shape that provides a stable contact point with the ground and allows the support to stand. Alternatively, the support 900 may not include a support member 904. The third contact point may be due to the body 901 of the support resting on the ground and providing stability for the support 900. The support can have multiple legs and multiple points of contact on the ground. Such alternative modalities are also within the scope of this specification. [000171] An additional alternative form of the support with legs is shown in figure 10. Support 1000 can include only two legs 1002, 1003, as shown in figure 10. Support 1000 includes a support body 1001. The support body can be substantially similar to the support body 901 described with reference to figure 9. Support body 1001 is preferably U-shaped as seen in figure 10, but could be curved in any other way. The support 1000 holds the discharge arm in such a way that the filter is not the lowest point of the arm 301. The lowest point of the arm is preferably the most arm point of the U-bend. The support body 1001 may include a receiving characteristic 1005 at each end of the support body 1001. The receiving characteristic is preferably a slot, but it could be a ring, groove or clip. The receiving feature 1005 receives and retains the discharge arm 301 in the correct orientation. The discharge preferably mounts within the receiving characteristics 1005. The support body 1001 may also include a channel 1006 for receiving and retaining the discharge arm 301 within it. The legs 1002, 1003 are specifically designed to keep the support stable when in contact with the ground. The legs can be formed so that one leg is larger than the other, the large leg having a large area of contact with the ground with a smaller leg providing stability and a second point of contact. An example of this is shown in figure 10 with leg 1003 being the longest and leg 1002 being the shortest leg. [000172] In an additional alternative form the support may include a stabilizing mass attached to it, or housed within it. The stabilizing mass (not shown) can be a moving weight such as fluid or ball bearings or any other suitable moving weight. Preferably the stabilizing mass can be housed within one of the legs of the support 900. The stabilizing mass can also be housed within the body 901 of the support 900. Preferably the support is housed substantially in the middle of the support or connected close to the middle of the support , for example, the stabilizer mass can be housed inside or connected near the lowest point of the U-shaped body 901 of the support. Most preferably the stabilizing mass is housed within the support member 904 or connected close to the position where the support member 904 attaches to the support. In an alternative the legs 1002, 1003 of the support 1000 can include a stabilizing mass inside one or both legs 1002, 1003. In an additional alternative one of the legs of the support can be larger than the other and heavier than the other leg or legs. The larger leg can act as a stabilizing mass due to its size or shape or a combination thereof. The support leg can take any suitable shape that allows it to act as a stabilizing mass. The stabilizing mass can be formed from any suitable material such as a metal. Preferably the material of the stabilizer mass can be heavier than the support to allow the stabilizer mass to effectively stabilize and correctly orient the support when in use. In an additional alternative, the support may include multiple stabilizing masses to stabilize the support and ensure that the support is oriented in the correct way. The stabilizing mass or masses are advantageous because the stabilizing mass stabilizes the support and ensures that the support is in the correct orientation in use. The stabilizer mass counteracts any forces or moments that may be applied to the support while in use, for example, due to the arm 301 being pulled or the support 900 or 1000 being bumped. The stabilizer mass adds stability to the support to ensure that the support remains in the correct orientation. Moving the support in its correct orientation can cause condensation to run towards the filter or can damage the arm 301 or the filter 303. Support 900 being in the wrong orientation can also lead to other adverse effects on the smoke evacuation system . The stabilizer mass helps to stabilize the support so that it remains in the correct orientation. [000173] In an alternative form the support may have no legs, as shown in figures 11 and 12. A support without legs can be used when the discharge arm is not long enough to contact the floor. A modality of a support without legs is shown in figure 11. Support 1100 can be attached to another feature such as a wall or a bed leg. The fixation can be permanent, for example, by a fixing mechanism or set, or the fixation can be temporary, for example, by a non-permanent adhesive, or features such as hook and loop. In an additional alternative form, the support can be adhesively attached to another feature. The support 1100, as seen in figure 11 preferably includes a support body 1101. The support body 1101 is substantially similar in shape to the support body 901 shown in figure 9. Support 1100 is substantially U-shaped but alternatively the support 1100 can be any other curved shape. The holder receives and retains the arm 301 and secures the arm 301 in the preferred orientation, where the filter 303 is pointing away from the ground. Holder 1100 secures arm 301 in a way that the filter is not the lowest point on the arm. Support 1100 may also include a receiving feature 1105 at either end or at each end of the support. The receiving feature 1105 is preferably a slot, but it can be a groove, ring or clip. The receiving feature 1105 receives and retains the discharge arm 301 in the correct orientation. The support body 1101 can also include a channel or groove 1106 in it. Channel 1106 acts to receive and retain arm 301 within it. The discharge arm 301 preferably mounts within the receiving characteristic 1105 and the channel 1106 by fitting. Alternatively the arm 301 can be clipped inside or retained by the receiving characteristics 1195 in any other suitable mode. The support without any legs can also include a stabilizing mass inside the support body 1101 or attached to the support body 1101. In another additional form the stabilizing mass can be a projecting member of the support body. The member can act to counteract any forces or moments applied to the support during use, so that the support remains in the correct orientation. [000174] An additional alternative form of a legless support 1200 is shown in figure 12. Such a legless support is preferably used with a discharge member that is not long enough to contact the floor. In one form the holder can be a retaining member 1200 that extends from the filter 303 and engages with a part of the discharge arm 301. The retaining member 1200 is preferably an elongated member that extends out of the filter and engages with part of the arm 301 to bend or contort the arm in a substantially U-shape, as shown in figure 12. Retention member 1200 may include a retention feature 1201 at one end. Retention feature 1201 can be a hook or a loop. The discharge arm 301 mounts within the retaining characteristic 1201. Alternatively, the support 1200 can be a clip which can open and close to receive and secure the arm 301. Preferably the retaining member 1200 can be formed integrally with the filter. Alternatively, the retaining member 1200 may have a second retaining feature (not shown) on the opposite end of the first retaining feature 1201 which it engages with the arm 301, preferably at a point adjacent to the filter 303. The retaining member 1200 can be formed of a rigid material such as plastic or metal. [000175] As an additional alternative, the support may not attach and retain the discharge arm within it. The rigid support can be hollow and tubular in shape, so that it forms a sealed gas path and allows smoke to flow through it and out towards the filter. A first end of the support can be connected to the outlet end of the discharge arm and the second end of the support is connected to the filter. The gases and / or smoke from the surgical site travel from the discharge arm to the filter through the support. In another form, the second end of the filter can be connected to a secondary arm that connects between the support and the filter. The secondary arm can also be similar in structure and material to the discharge arm. The secondary duct is substantially flexible and preferably at least part of the secondary duct is formed of a breathable material so that the breathable material allows water vapor to pass out of the secondary duct into the ambient air without allowing liquid or surgical smoke and / or gases. [000176] The support connects to the discharge arm, the filter and / or the secondary duct by a threaded connection. Alternatively, the support can have couplers on both ends that connect the support to the discharge arm, the filter and / or the secondary duct. In an additional alternative arrangement the support can be connected to the discharge arm, the filter and / or the secondary duct by welding plastic or solvent. WATER LACKING ALARM [000177] In an insufflation system that incorporates a humidification chamber, a minimum water level must be maintained inside the humidification chamber so that the humidification chamber has the capacity to humidify incoming gases. The inflation system 100 can be used with the smoke evacuation system 300. When combined, the smoke evacuation system includes a humidification chamber 103 and a heater base 102 attached to it and a gas source that supplies the gases to the humidification chamber and then into the surgical site. The humidification chamber 103 requires a minimum water level to allow the humidification chamber to properly humidify incoming gases. Consequently, a healthcare professional or person using the insufflation system needs to keep checking the water level inside the humidification chamber and add more water when required. This job can be tedious and neglected. [000178] One way to measure the amount of water and determine a low or no water condition inside the humidification chamber 103 is to use a flow probe which automatically determines when the water level drops to an insufficient level and triggers a alarm. [000179] The preferred method for measuring and monitoring the amount of water inside the humidification chamber will be described. A low water condition, no water or lack of water as referred to in this specification means that there is either no water or a very low water level within the humidification chamber. A very low water level corresponds to a water level that is insufficient to humidify the insufflation gases. The method for determining a waterless condition within a humidification chamber 103 involves measuring the outlet temperature of chamber 103, the energy supplied to the heater base 102 and a change in the flow of gases through or into chamber 103. A condition without water refers to zero water level or very low water level inside chamber 103. Chamber 103 humidifies the insufflation gases by passing them through the water vapor created inside chamber 103. Chamber 103 includes a volume of water that is heated by the heater plate 102. At least part of the water inside the chamber 103 becomes water vapor when heated by the heater 102. The insufflation gases that flow through the chamber collect the water vapor and are humidified. The water inside the chamber 103 decreases due to continuous use and falls to a point where there is not enough water to humidify the insufflation gases. The method described below is the method implemented by the controller to detect a low water level, but more preferably a zero water level condition within chamber 103. [000180] The method involves measuring the outlet temperature of the chamber 103, more specifically measuring the temperature of the gases leaving the chamber 103. As the water inside the chamber reduces to a level where the gases are not adequately humidified, the temperature of the output reduces. This is because the water vapor given to the gases by humidification can be at a higher temperature than the gases. The temperature of the gases leaving the chamber 103 decreases when there is little or no water inside the chamber 103 because there is no energy transferred to the gases by the water vapor. The temperature of the gases leaving chamber 103 is adjusted by controller 104. The outlet temperature is programmed in controller 104 based on the type of operation and the amount of humidity required for the insufflation gases. The controller 104 attempts to counteract the decrease in the outlet temperature by increasing the active heater cycle to increase the heat provided by the heater base 102. In the preferred method the controller measures a decreasing temperature of gases leaving chamber 103 while also monitoring the response of the heater base. If the temperature of the gases leaving the chamber drops continuously while the energy supplied to the heater base is constant or increasing, it indicates a low or no water situation inside the chamber. Controller 104 alerts the user, sounds an alarm, or turns off the heater plate power when a low or no water situation is detected. The controller preferably turns off the power to the heater base. In addition, the controller can also alert the user by ringing a bell or displaying a message on a screen 106 attached to the insufflator 101. [000181] The method also measures the flow rate of gases flowing through chamber 103 for a more accurate measurement of the low or no water situation. The temperature of the gases leaving the chamber 103 can also drop if the flow rate of the gases entering and flowing through the chamber 103 increases. The increased flow rate causes a greater volume of insufflation gas to pass through chamber 103. The greater volume of gases requires more energy from the water vapor, thereby leading to a drop in temperature as the gases exit. A higher gas flow rate requires a greater amount of water vapor for the gases to be humidified to an appropriate level. The controller compensates for the increased gas flow by increasing energy to the heater base in order to cause more water inside the chamber 103 to evaporate so that the gases are humidified to an appropriate level. In order to determine a low or no water condition inside the chamber, controller 104 also monitors the rate of gas flow through the chamber 103. A low or no water condition inside the chamber 103 is determined when the gases that flowing through the chamber are not increasing. [000182] Controller 104 measures the outlet temperature of the chamber, meaning the temperature of the gases flowing out of the chamber 103. The controller also measures the energy supplied to the heater base 102 and measures the rate of gas flow through the chamber 103. A low or no water condition is determined if there is a drop in the temperature of gases leaving chamber 103, while the energy for the heater base is constant or increasing and the rate of gas flow through chamber 103 it is substantially constant or not increasing. If the temperature of the gases leaving chamber 103 begins to drop, controller 104 increases power to the heater base 102. Controller 104 can determine a low or no water condition if the temperature of gases leaving chamber 103 and the energy for the heater base 104 diverges from one another. This means if the temperature of the gases leaving the chamber 103 is continuously decreasing while the energy supplied to the heater base 102 increases continuously. Low or no water is confirmed if for at least two minutes the controller determines that the temperature of the gases leaving the chamber 103 is decreasing, the energy supplied to the heater is constant and increasing and the rate of gas flow through the chamber 103 is constant and not increasing. [000183] The temperature of the gases leaving the chamber can be measured using any suitable temperature sensor. The flow rate of the gases entering the chamber 103 can also be measured by any suitable flow sensor. The preferred sensor for measuring the gas flow rate is the hot wire flow sensor like a hot wire anemometer. The temperature sensor can also be a wire-based temperature sensor. In the preferred form the temperature sensor and the flow sensor are within the same housing. Hot wire flow sensors may experience a reduction in flow due to the reduced cooling effect of the lower unit gases. This usually occurs when there is a low or no water condition inside the chamber. The gases that flow through the chamber are improperly humidified or not humidified at all. The lower humidity gases have a cooling effect on the wire probe of the hot wire sensor thus causing the sensor to emit an increased flow rate reading. The controller also checks for a reduction in flow rate due to this cooling effect. A reduction in the flow rate, a reduction in the temperature of the gases leaving the chamber 103 and an increased or constant energy for the heater plate all correspond to a low or no water condition inside the chamber. In an attempt to reduce false alarms, the Waterless test only works in a low flow case. When the controller detects a low flow situation, it executes the sketched method to measure the water level inside the humidification chamber. The low flow empirically acts as a good filter for false alarms. This method is preferably stored in ROM and implemented by the software-based controller. Alternatively, the method of measuring the water level can be implemented as an analog electronic circuit. As an additional alternative the method can be implemented as a digital circuit using flip flops, couplings, etc. [000184] Although the invention or inventions are susceptible to modalities in different forms, specific modalities are shown in the drawings, and described in detail above. The present description is to be considered as an exemplification of the principles of the invention, and is not intended to limit the invention to what has been illustrated and described herein. EXAMPLE 1 PURPOSE: [000185] The purpose of this test was to compare the accumulation of condensation when using a breathable tube versus a PVC tube when combined with a laparoscopic smoke evacuation filter in conjunction with the Fisher & Paykel Healthcare MR860 Humidification System. [000186] A test was performed to compare the difference between using a non-breathable PVC pipe as the discharge arm in a smoke evacuation system 300 and using a duct which is at least partially breathable. The test configured to measure which type of duct or pipe resulted in the least amount of condensation forming inside the discharge duct and the filter trapped in the discharge duct. The test used experimental equipment to simulate the conditions that would normally be found inside an inflated abdominal cavity undergoing surgery. [000187] The method steps as performed by the inventors to perform the test are described below: METHOD: [000188] Step 1: Set up the patient model with two holes in the cover 20 cm apart, as shown in figure 4 by reference 10. Seal the top of each hole with a thin piece of silicone. The silicone will have a hole of 50% of the cannula diameter. Add 1 L of water to the model and seal the patient model cap on the container with a silicone sealant. Isolate the patient model entirely with polystyrene or a similar insulator. Use a tissue over the cover and edges to cover the entire patient model. [000189] Step 2: Adjust the air temperature of the patient model to 37 ° C. Make the 11 mm cannula hole open and the 5.5 mm cannula hole closed. Configure the MR860 heater base and RT350 system as detailed in your user instructions. Connect the luer end of the heated arm to the 11 mm cannula hole. [000190] Step 3: Adjust the insufflator pressure to 12 mm / Hg and the flow rate to 3 L / min. Connect the carbon dioxide bottle and make sure that the insufflator indicates that a gas remains inside the bottle. Start the gas flow and connect the heater base. [000191] Step 4: Measure and record the dry weight of the complete smoke evacuation system. In case the scales are too small to accommodate the entire piping set, use a rigid plate and then zero the scales before placing the piping set on top as shown in figure 5. [000192] Step 5: Connect the luer of the smoke evacuation system to the 5.5 mm cannula hole. Set up the tubing as shown in figure 4 so that the tubing tilts down slightly after the luer so that any condensation will accumulate on the bottom. The filter must be at a significant height above the outlet cannula orifice as shown in figure 6. [000193] Step 6: The configuration should look like figure 7. Note that in this figure the insufflator, MR860 and MR730 were not connected as they should. This figure is only intended to provide a general impression of the design of the experiment. [000194] Step 7: Once the heater base and patient model have stabilized at their correct temperatures, open the 5.5 mm cannula gas hole fully to allow the gas to move out of the cannula and through of the smoke evacuation system. Reset the volume of gas in the insufflator. Let the experiment run for 60 minutes, then turn off the 5.5 mm cannula gas orifice to stop the flow through the smoke evacuation system. Stop the inflator gas flow. [000195] Step 8: Carefully disconnect the smoke evacuation system from the cannula ensuring that no condensation is split at either end (ie, trapped in a 'U' fold shape). Measure and record the wet weight of the complete smoke evacuation system, similar to step 4. If the scales are too small to accommodate the entire piping set, use a rigid plate and then zero the scales before placing the piping set on top. [000196] Step 9: Once the weight has been registered remove the blue filter tip and connect an air line at the top of the filter as shown in figures 8a and 8b. Flush with dry air for 10 minutes at a low flow rate to dry the filter and tube. Reconnect the blue filter tip and weigh the tubing set as in step 4 in preparation for the next test. [000197] Step 10: Change the flow rate to 6 L / min. Check that there is enough water inside the RT350 chamber and top up if necessary. Start the gas flow again and wait for the heater base and patient model to stabilize at their correct temperatures. Repeat steps 5 to 9. [000198] Step 11: There are 8 tests in total. Breathable tubing with the combined Clearflow smoke filter is tested twice at 6 L / min and twice at 3 L / min. The same is repeated for the PVC Clearflow Smoke Evacuation System. RESULTS: [000199] A summary of the results is shown below in Table 1 Table 1 - Results Table [000200] The results show that using the Breathable tube tubing reduced the amount of condensation accumulation by 33.7% when compared to the PVC tubing when the insufflator is set to 6 L / min. Similarly, the results show that using Breathable tubing reduces the amount of condensation build-up by 19.6% when compared to PVC tubing when the insufflator is set to 3 L / min. [000201] When testing the smoke evacuation filter system with the PVC pipe there was a significant accumulation of condensation on the pipe walls just above the filter despite being higher than the exit orifice cannula. This was not the case with the Breathable tube. The Breathable tube was connected to both the luer and the filter with a small piece of PVC tube, see figure 6. During the test there was significant condensation on the PVC tube walls that connects the luer to the breathable tube, but no condensation on the tube that connects the breathable tube to the filter. [000202] The results of this experiment clearly show that the smoke evacuation system with a breathable duct was more efficient than the standard smoke evacuation system. This is because there is reduced condensation formed on the pipe or filter of the smoke evacuation system with a breathable duct.
权利要求:
Claims (21) [0001] 1. Discharge arm (301) for use in a surgical smoke evacuation system (300) to evacuate surgical smoke and gases from a surgical site within or on a patient, characterized by the fact that it comprises: a flexible elongated hollow body that defines a gas transport path to transport the smoke and gases created in surgical procedures, said body having an end of the operating room adapted for connection to the surgical site, an outlet end adapted to connect to a filter (303), said surgical smoke and gases substantially moving from said surgical site to said filter (303) through said elongated hollow body, the elongated hollow body being at least partially constructed of a breathable material or having one or more regions of breathable material that allow for passage of water vapor out of the elongated hollow body through the regions or breathable material while restricting the passage of liquid water or smoke surgical and gases. [0002] 2. Discharge arm (301), according to claim 1, characterized by the fact that said water vapor is passed from the elongated body to the ambient air through the region or breathable material. [0003] Discharge arm (301), according to claim 1 or 2, characterized in that said arm (301) still includes an air jacket coaxially arranged with said elongated hollow body, said air jacket covering and closing said elongated hollow body, said water vapor passing through the region or breathable material into said air jacket. [0004] Discharge arm (301) according to any one of claims 1 to 3, characterized in that the region or breathable material is selected from the group consisting of a hydrophilic thermoplastic, a perfluorinated polymer and a treated braided fabric. [0005] Discharge arm (301) according to any one of claims 1 to 4, characterized in that the discharge arm (301) is between 400 mm and 1500 mm in length. [0006] 6. Surgical smoke evacuation system (300) for use in removing gases and smoke created in surgical procedures from within an inflated surgical cavity, said cavity of the type that has at least one opening adapted for gas discharge, characterized by fact of understanding: a discharge set (302) adapted to form a gas path, and which has an end which in use is located within said surgical cavity so that the gases and / or surgical smoke within said cavity can pass out of said cavity and through said discharge assembly (302) along said gas path, a flexible discharge arm (301) as defined in any one of claims 1 to 5, the end of the operating location of the flexible discharge arm (301) being sealed in use to the discharge assembly (302) so that said gases and / or surgical smoke can pass out of the discharge assembly (302) and even a inside the discharge arm (301), a filter (303) in use connected to the outlet end of the discharge arm (301). [0007] 7. Surgical smoke evacuation system (300) for use in removing gases and smoke created in surgical procedures from inside an inflated cavity, said cavity of the type that has at least one opening adapted for gas discharge, characterized by the fact to be understood: a discharge set (302) adapted to form a gas path, and which has an end which in use is located within the surgical cavity so that gases and / or surgical smoke within said cavity can pass out of the cavity and through said discharge assembly (302) along said gas path, a flexible discharge arm (301) that has an end of operating location and an outlet end, and a self-supporting wall that defines a passage of gas flow between the end of the operating site and the outlet end, in use the end of the operating site sealingly connected to the discharge assembly (302) so that the gases and / or surgical smoke can pass out of the discharge assembly (302) and into the discharge arm (301), a filter (303) in use connected to the outlet end of the discharge arm (301), a support (320, 900, 1000, 1100, 1200) adapted to receive and retain said discharge arm (301) in such a way that said arm (301) is folded along part of the length of the discharge arm (301 ) where the support (320, 900, 1000, 1100, 1200) contacts the arms (301), so that in use the fold along part of said length of the discharge arm acts to collect any condensation formed inside the discharge arm discharge (301), said arm (301) being folded so that in use said filter (303) is not the lowest point of said arm (301). [0008] System (300) according to claim 7, characterized in that the discharge arm (301) comprises the discharge arm (301) as defined in any one of claims 1 to 5. [0009] 9. System (300) according to claim 7 or 8, characterized in that said support (320, 900, 1000, 1100, 1200) is a retaining member (1200) extending from said filter (303 ), said retaining member (1200) coupling with said arm (301), said arm (301) being bent or contorted by said retaining member (1200), so that said filter (303) is not the lowest point of said arm (301). [0010] System (300) according to any one of claims 7 to 9, characterized in that said retaining member (1200) is attached to said filter (303) at one end of said retaining member (1200) , an opposite end of said retaining member (1200) including a retaining feature (1201) adapted to receive and retain said arm (301) upstream of said filter (303) so that said arm (301) is folded or contorted so that said filter (303) is not the lowest point of said arm (301). [0011] 11. Smoke evacuation system (300) according to any one of claims 7 to 10, characterized in that said arm (301) is bent or contorted to form a U-fold in use, said fold in U acting as a siphon so that any condensation or liquid within said arm flows towards said U-fold and accumulates near the lowest point of said U-fold. [0012] 12. Smoke evacuation system (300) according to any of claims 7 to 11, characterized by the fact that said support (320, 900, 1000, 1100, 1200) maintains at least two points of contact with the soil to form a stable structure for retaining and securing said smoke evacuation arm (301). [0013] 13. Smoke evacuation system (300) according to any of claims 7 to 12, characterized in that said support (320, 900,1000,1100,1200) comprises a body (901, 1001, 1101 ) having a first end and a second end, said first end connecting at the outlet end of said discharge arm (301), said second end of said support (320, 900, 1000, 1100, 1200) connecting to a substantially flexible secondary conduit, said filter (303) connected to said secondary conduit, said support (320, 900, 1000, 1100, 1200) forming a sealed gas path to allow the flow of gases and / or smoke from the end of exit of said discharge arm (301) to said secondary duct, said gases and / or smoke moving through said support (320, 900, 1000, 1100, 1200). [0014] 14. Smoke evacuation system (300) according to any one of claims 7 to 13, characterized in that said support (320, 900, 1000, 1100, 1200) includes at least one stabilizing mass within the support (320,900,1000,1100,1200) or attached to the support (320, 900, 1000, 1100, 1200), said stabilizing mass stabilizing the support so that said support (320, 900,1000,1100,1200) and the arm (301) remains in a correct orientation. [0015] 15. Smoke evacuation system (300) according to any of claims 7 to 14, characterized in that said support (320, 900, 1000, 1100, 1200) and / or said secondary duct are formed partially of a breathable material. [0016] 16. Smoke evacuation system (300) according to any of claims 7 to 15, characterized in that it is a passive smoke evacuation system, said surgical cavity being pressurized due to an insufflation gas being pumped to within said surgical cavity of a pressurized gas source so that said conduit has a higher pressure at the end of the operating location than at said outlet end, said outlet opening downstream open to the atmosphere. [0017] 17. Apparatus for use in determining a low or no water condition in a humidification chamber (103), characterized by the fact that it comprises: devices for measuring the energy supplied to a heater (102) capable of heating said chamber humidification devices (103), devices for measuring the temperature of gases leaving said humidification chamber (103), devices for measuring the rate of gas flow through said humidification chamber (103), devices for determining a water condition low or no water based on a reduced temperature of said gases leaving said humidification chamber (103), while said energy supplied to said heater (102) is constant or increasing and said gas flow through said humidification chamber (103) is constant for a predetermined time. [0018] Apparatus according to claim 17, characterized in that it further comprises devices for disconnecting power to said heater (102) if a low or no water condition is measured. [0019] 19. Apparatus according to claim 17 or 18, characterized by the fact that it also comprises devices to alert a user when a low or no water condition is detected. [0020] 20. Insufflation system (100), characterized by the fact that it comprises: a gas source (107), a humidification chamber (103) adapted to contain a volume of water that has an inlet and an outlet, said inlet of said humidification chamber (103) in gas communication with said gas source (107) for receiving gases from said gas source, said gases entering through said inlet and passing through said outlet of said humidification chamber (103 ), a conduit (105) having a first end and a second end, said first end connected to said outlet of said humidification chamber (103), said first end of said conduit (105) in gas communication with the said humidification chamber outlet and receiving said humidified gases from said humidifier, said second end of said conduit (105) in communication with a surgical site and providing said humidified gases to said surgical site, a heating base r (102) provided adjacent to said humidification chamber (103), said heater base (102) providing heat for said amount of water within said humidification chamber (103) in order to provide water vapor for said gases flowing through said humidification chamber (103), a first temperature sensor attached to said heater base (102) and monitoring the temperature of said heater base (102), a second temperature sensor attached adjacent to said outlet of said humidification chamber (103), said second temperature sensor monitoring said temperature of said humidification chamber (103), a controller (104) adapted to control the heat provided by said heater base (102) for said humidification chamber (103), said controller (104) connected to said first and second temperature sensors and receiving temperature information from said sensors. [0021] 21. Insufflation system (100) according to claim 20, characterized by the fact that it comprises an apparatus for use in determining a low or no water condition within said humidification chamber (103), according to any one of claims 17 to 19.
类似技术:
公开号 | 公开日 | 专利标题 BR112012015601B1|2020-07-14|DISCHARGE ARM FOR SURGICAL SMOKE EVACUATION SYSTEM, SURGICAL SMOKE EVACUATION SYSTEM, APPLIANCE FOR WATER CONDITION DETERMINATION INSIDE A HUMIDIFICATION CHAMBER AND INSUFLATION SYSTEM AU2019250204B2|2021-12-23|Humidification system ES2842077T3|2021-07-12|Apparatus for measuring the properties of gases delivered to a patient ES2369850T3|2011-12-07|RESPIRATORY HUMIDIFICATION SYSTEM. CA2495451C|2011-08-09|Humidification system CN106456929B|2020-01-21|Method and system for delivering gas to a patient CN103037926B|2016-06-29|Water Out alarm JP2008161712A|2008-07-17|Humidification apparatus JP2015503388A|2015-02-02|Respiratory measurement device with integrated filter JP2003111774A|2003-04-15|Heating and humidifying device for pneumoperitoneum gas and pneumoperitoneum apparatus CN105163783B|2018-05-29|For celioscopy pipe is blown into heating element JP2015521887A|2015-08-03|Compact humidifier TW202029989A|2020-08-16|Venting surgical cannula for providing gases to a patient CN110191737A|2019-08-30|Filter assemblies AU2012101083A4|2012-08-16|Improvements relating to systems for laparoscopic surgery ES2895414T3|2022-02-21|System to avoid cross contamination in flow generation systems JP6893629B2|2021-06-23|Double lumen breathing circuit system with lung pressure measurement port and water trap with closed system that allows drainage with injectors JP2021533846A|2021-12-09|Breathing device with improved humidification of breathing gas BR112018002661B1|2021-11-30|DUAL-LUMEN RESPIRATORY CIRCUIT SYSTEMS AND COAXIAL RESPIRATORY CIRCUIT SYSTEMS BR112021001373A2|2021-04-20|device to remove heat, energy and / or fluid from a living mammal CN112672778A|2021-04-16|Respiratory device with condensation protection in a patient interface
同族专利:
公开号 | 公开日 CN203315068U|2013-12-04| GB2489183A8|2012-09-26| DE212010000199U1|2012-08-21| WO2011078701A1|2011-06-30| GB2489183A|2012-09-19| GB201213021D0|2012-09-05| US9474512B2|2016-10-25| GB201602952D0|2016-04-06| US10426902B2|2019-10-01| US20170136195A1|2017-05-18| GB201613042D0|2016-09-14| GB2489183B|2016-06-08| US20130131580A1|2013-05-23| BR212012015601U2|2015-11-17| GB2538425A|2016-11-16| US20190351157A1|2019-11-21| GB2538425B|2017-07-19| GB2534487B|2016-10-05| GB2534487A|2016-07-27|
引用文献:
公开号 | 申请日 | 公开日 | 申请人 | 专利标题 US1156145A|1915-06-05|1915-10-12|Allen R Jenkins|Pipe-coupling.| US3897923A|1971-12-13|1975-08-05|Ball Corp|Curvature maintaining device| US3783262A|1973-04-03|1974-01-01|Us Army|Portable surgical lamp| US3860978A|1973-05-18|1975-01-21|Paul H Wirth|Time saving drain assembly for sinks, bathtubs, etc.| US4028444A|1974-03-25|1977-06-07|Chemetron Corporation|Humidifier and automatic control system therefor| US4151864A|1975-03-31|1979-05-01|Arundale, Inc.|Drain adapter for corrugated hose| US4284878A|1979-08-20|1981-08-18|Bourns Medical Systems, Inc.|Fluid level detector| US4441027A|1981-08-03|1984-04-03|Baxter Travenol Laboratories, Inc.|Liquid level controller for a respiratory gas humidifier device| US4682010A|1983-03-07|1987-07-21|Safeway Products, Inc.|In-line electric heater for an aerosol delivery system| US4922554A|1988-09-19|1990-05-08|Hwang Jin Chyuan|Retainer for flexible drain pipes| GB8827075D0|1988-11-19|1988-12-21|Jessup M B|Diffusion membrane water trap| WO1991014476A1|1990-03-22|1991-10-03|Methodist Hospital Of Indiana, Inc.|Exhaled gas cooling device| US5065785A|1990-08-24|1991-11-19|Armstrong International, Inc.|Steam trap with separate steam and condensate inlets| US5226939A|1991-10-22|1993-07-13|Stackhouse, Inc.|Surgical smoke evacuation system| US5346075A|1992-04-17|1994-09-13|Johnson & Johnson Medical, Inc.|Apparatus and method for holding a medical instrument| US5442157A|1992-11-06|1995-08-15|Water Heater Innovations, Inc.|Electronic temperature controller for water heaters| US5578000A|1993-01-21|1996-11-26|Stackhouse, Inc.|Laparoscopic smoke evacuation system| JP2781164B2|1995-12-28|1998-07-30|三鷹光器株式会社|Auto-balance structure of medical stand device| CA2222830C|1996-12-02|2004-03-30|Fisher & Paykel Limited|Humidifier sleep apnea treatment apparatus| CA2443306C|1997-06-17|2005-11-22|Fisher & Paykel Limited|Respiratory humidification system| US20040221844A1|1997-06-17|2004-11-11|Hunt Peter John|Humidity controller| US6110259A|1997-11-21|2000-08-29|Jlj International, Inc.|Smoke evacuation system| US6068609A|1998-05-19|2000-05-30|Douglas E. Ott|Method and apparatus for conditioning gas for medical procedures having humidity monitoring and recharge alert| US6095505A|1998-07-15|2000-08-01|Pegasus Research Corporation|Patient-end humidifier| US6311936B1|1999-07-30|2001-11-06|Maytag Corporation|Hose retainer| US6523538B1|2000-01-05|2003-02-25|Instrumentarium Corp.|Breathing circuit having improved water vapor removal| BR0102116B1|2000-05-10|2010-09-21|component for a breathing circuit member.| US6469282B1|2000-07-28|2002-10-22|General Electric Company|Boil dry detection in cooking appliances| CA2424647C|2000-10-16|2009-09-08|Fisher & Paykel Healthcare Limited|Improvements to apparatus used for the humidification of gases in medical procedures| CA2437057C|2001-01-31|2012-04-24|Hemerus Medical, Llc|Biological fluid filtration system| NZ527089A|2001-02-16|2005-09-30|Resmed Ltd|Air pressure signal monitoring in apparatus for treating sleep disordered breathing| US7140367B2|2002-02-20|2006-11-28|Fisher & Paykel Healtcare Limited|Conduit overheating detection system| US7086399B2|2002-05-29|2006-08-08|Fisher & Paykel Healthcare Limited|Apparatus for delivery of humidified gases therapy, associated methods and analysis tools| DE10234811C1|2002-07-31|2003-11-27|Draeger Medical Ag|Humidification system for gases respired by patient, includes water reservoir system isolated from surroundings and connected by feed- and vent lines to water boiler| US7306205B2|2002-08-30|2007-12-11|Fisher & Paykel Healthcare Limited|Humidification system| US7488315B2|2003-09-05|2009-02-10|Medical Designs, Llc|Surgical smoke field evacuators| US7216676B2|2004-04-30|2007-05-15|Eaton Corporation|Apparatus and method for shaping hose| EP1804876B1|2004-08-10|2019-12-25|ResMed Pty Ltd|Apparatus for humidification of breathable gas with profiled delivery| FR2875138B1|2004-09-15|2008-07-11|Mallinckrodt Dev France Sa|CONTROL METHOD FOR A HEATING HUMIDIFIER| US7473868B2|2005-06-30|2009-01-06|R. W. Beckett Corporation|Fail safe HVAC temperature and medium presence sensor| US8640696B2|2005-07-07|2014-02-04|Ric Investments Llc|System and method for determining humidity in a respiratory treatment system| WO2007019628A1|2005-08-15|2007-02-22|Resmed Ltd|Low cost cpap flow generator and humidifier assembly| US20070137484A1|2005-12-21|2007-06-21|Porous Media|Operating room body gas evacuation system| WO2007095641A2|2006-02-16|2007-08-23|J2 Scientific, Llc|Automated solvent evaporation system| DE102006018423A1|2006-04-20|2007-10-25|BSH Bosch und Siemens Hausgeräte GmbH|Refrigerating appliance with a condensate drainage system| US20070272239A1|2006-04-24|2007-11-29|Acoba, L.L.C.|Dual chamber humidifier| US7819957B2|2006-06-14|2010-10-26|Keith Roberts|Operating room filter systems| US8511305B2|2007-10-29|2013-08-20|Smiths Medical Asd, Inc.|Redundant power control for respiratory system heaters| US7983542B2|2007-10-29|2011-07-19|Smiths Medical Asd, Inc.|PID coefficient adjustment for respiratory heater closed loop control| US20090134282A1|2007-11-26|2009-05-28|Grim Sr Glenn R|Pipe clamp| US8269638B2|2008-01-23|2012-09-18|Lexion Medical Llc|Hydration alert| US9802022B2|2008-03-06|2017-10-31|Resmed Limited|Humidification of respiratory gases| GB2460645A|2008-06-02|2009-12-09|Plamen Spassov Vassilev|Bathtub Heater| JP2010054173A|2008-08-29|2010-03-11|Sharp Corp|Cooker| US8844522B2|2008-09-10|2014-09-30|Resmed Limited|Power management in respiratory treatment apparatus| US8757509B2|2009-03-27|2014-06-24|Honeywell International Inc.|Boiler control methods| US8869679B2|2009-10-08|2014-10-28|Gold Medal Products Company|Automatic power shut-off to at least a portion of a cooking apparatus| CN102740918B|2009-12-23|2016-02-24|费雪派克医疗保健有限公司|Humidified gases conveyer device and control method thereof| BR112012015601B1|2009-12-23|2020-07-14|Fisher & Paykel Healthcare Limited|DISCHARGE ARM FOR SURGICAL SMOKE EVACUATION SYSTEM, SURGICAL SMOKE EVACUATION SYSTEM, APPLIANCE FOR WATER CONDITION DETERMINATION INSIDE A HUMIDIFICATION CHAMBER AND INSUFLATION SYSTEM|BR112012015601B1|2009-12-23|2020-07-14|Fisher & Paykel Healthcare Limited|DISCHARGE ARM FOR SURGICAL SMOKE EVACUATION SYSTEM, SURGICAL SMOKE EVACUATION SYSTEM, APPLIANCE FOR WATER CONDITION DETERMINATION INSIDE A HUMIDIFICATION CHAMBER AND INSUFLATION SYSTEM| CN102740918B|2009-12-23|2016-02-24|费雪派克医疗保健有限公司|Humidified gases conveyer device and control method thereof| JP5968886B2|2010-08-04|2016-08-10|ミニマリー インべーシブ デバイシーズ, インコーポレイテッド|System and method for optimizing and maintaining operative field visualization while using a surgical microscope| DE102012110889A1|2012-11-13|2014-05-15|Karl Storz Gmbh & Co. Kg|Device for insufflation of visceral cavity with insufflation gas by insufflator, has discharge line that is provided for discharging gases from visceral cavity, which is communicated with humidity sensor| ES2626558T3|2013-01-15|2017-07-25|W.O.M. World Of Medicine Gmbh|Flexible insufflation tube with humidification material and heating element for laparoscopy| US10398292B2|2013-03-14|2019-09-03|Floshield, Inc.|Fluid dispensing control systems and methods| GB2524755B|2014-03-31|2016-07-06|Laprosurge Ltd|Variable flow smoke evacuation apparatus| CA2945749A1|2014-04-16|2015-10-22|Fisher & Paykel Healthcare Limited|Methods and systems for delivering gas to a patient| EP3536366B1|2014-05-15|2021-01-06|Fisher&Paykel Healthcare Limited|Active smoke filtration for insufflation| CA2965504C|2014-10-24|2020-01-07|Integrated Surgical LLC|Suction device for surgical instruments| US10926007B2|2015-07-13|2021-02-23|Conmed Corporation|Surgical suction device that uses positive pressure gas| US10821212B2|2015-07-13|2020-11-03|Conmed Corporation|Surgical suction device that uses positive pressure gas| CN205359424U|2015-11-30|2016-07-06|香港生产力促进局|Operation smog controlling means and peritoneoscope subassembly suitable for peritoneoscope| CN105796163B|2016-05-10|2019-01-25|安徽优尼科医疗科技有限公司|A kind of laparoscope filtering puncture outfit| WO2018039239A1|2016-08-22|2018-03-01|Poll Wayne L|Continuous gas supply insufflator having exhaust line peritoneal pressure control methods| US20190117858A1|2017-10-24|2019-04-25|Buffalo Filter Llc|Method and apparatus for filtering| USD868236S1|2017-11-29|2019-11-26|Megadyne Medical Products, Inc.|Smoke evacuation device control panel| US11234754B2|2017-11-29|2022-02-01|Megadyne Medical Products, Inc.|Smoke evacuation device| USD868287S1|2017-11-29|2019-11-26|Megadyne Medical Products, Inc.|Remote activation clip| US10631916B2|2017-11-29|2020-04-28|Megadyne Medical Products, Inc.|Filter connection for a smoke evacuation device| US10758293B2|2017-11-29|2020-09-01|Megadyne Medical Products, Inc.|Smoke evacuation device inlet and outlet manifolds| US10758855B2|2017-11-29|2020-09-01|Megadyne Medical Products, Inc.|Smoke evacuation system fluid trap| USD912762S1|2017-11-29|2021-03-09|Megadyne Medical Products, Inc.|Fluid trap| US10758856B2|2017-11-29|2020-09-01|Megadyne Medical Products, Inc.|Filter medium compression system for smoke evacuation| USD886976S1|2017-11-29|2020-06-09|Megadyne Medical Products, Inc.|Filter cartridge| USD894379S1|2018-05-23|2020-08-25|Fisher & Paykel Healthcare Limited|Insufflation circuit and filter| USD894376S1|2018-05-23|2020-08-25|Fisher & Paykel Healthcare Limited|Insufflation circuit assembly| CN110711432A|2018-07-12|2020-01-21|上海八凰实业有限公司|Supplementary smog filtration system device of laparoscopic surgery| EP3880269A1|2018-11-16|2021-09-22|Fisher & Paykel Healthcare Limited|A filter for a surgical procedure|
法律状态:
2020-04-07| B09A| Decision: intention to grant| 2020-06-09| B09W| Decision of grant: rectification|Free format text: RETIFICACAO DO DEFERIMENTO PUBLICADO NA RPI 2570 DE 07/04/2020 | 2020-07-14| B16A| Patent or certificate of addition of invention granted|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 20/12/2010, OBSERVADAS AS CONDICOES LEGAIS. |
优先权:
[返回顶部]
申请号 | 申请日 | 专利标题 US28961009P| true| 2009-12-23|2009-12-23| US61/289,610|2009-12-23| PCT/NZ2010/000257|WO2011078701A1|2009-12-23|2010-12-20|Improvements relating to systems for laparoscopic surgery| 相关专利
Sulfonates, polymers, resist compositions and patterning process
Washing machine
Washing machine
Device for fixture finishing and tension adjusting of membrane
Structure for Equipping Band in a Plane Cathode Ray Tube
Process for preparation of 7 alpha-carboxyl 9, 11-epoxy steroids and intermediates useful therein an
国家/地区
|