SE518424C2 - Smoke extractor for use with diathermy equipment - Google Patents

Abstract

The present invention relates to a smoke suction device and to a smoke extraction method for use together with smoke-generating surgical equipment. More specifically, the invention relates to a smoke suction device comprising a pump, a filter means, at least one suction nozzle, and sensing means for automatically activating the device. It is characteristic of the smoke suction device that the pump is a pneumatically operated ejector having no movable parts. The method for smoke extraction in connection with the use of smoke-generating surgical equipment is characterised in that a suction flow of at least some magnitude is established already before the surgical equipment is used and thereby generates smoke, and in that at least a reduced flow is established throughout most of the time when that same equipment is not active.

Description

25 30 35 n. U »a a u n. u - u oo o. v-. n ».nuu» nav I n -I n a. e nu o »nu nuo ~ u. nu o. nu» uno uovnuuu .non I vanua av u .no 2 336 218. However, the disadvantage of these smoke extraction devices is that the activation of the pumps only take place at the same time as the surgical equipment begins to be used and thus at the same time as the smoke generation starts. This means that during the first step, the smoke will not be taken care of in a way that is advisable from an infection control point of view. The problem also becomes even greater when the pumps used are mechanical and use pistons, fans or the like and typically have a start-up time of a few seconds.

In particularly infectious surgery (hepatitis, HIV, etc.), it is of extra importance that all smoke is taken care of.

It is furthermore a problem with the above-mentioned mechanical pumps that they are relatively large and clumsy, give a high noise level and generate a lot of heat. This in turn leads to the devices often not being used, as they are perceived as troublesome, which of course is not good in terms of infection control.

A further problem with the above-mentioned smoke suction devices is that the suction nozzle and connection hoses, due to the flow not taking place continuously, can be soiled and contaminated, which means a risk of infection for the patient when the equipment is to be used again after a break. It is especially dangerous, for example, with extracted cancer cells and the like that in this way can be spread and re-implanted in the body and thus give rise to new tumors.

Object of the invention The object of the present invention is to provide a smoke suction device which completely or at least partially obviates the problems with previously known smoke suction devices.

This object is achieved by a smoke suction device according to claim 1. Advantageous embodiments are stated in the subclaims. BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described in more detail, by way of example, with the aid of the accompanying drawings, which show: Fig. 1 a schematic view of the construction of an exemplary embodiment of a smoke suction device according to the invention; Fig. 2a is a timing diagram showing in parallel activation of a diathermy apparatus and activation of the suction device, for a first mode of operation of the suction device; Fig. 2b is a timing diagram as in Fig. 2a, for a second mode of operation of the suction device; Fig. 2c is a timing diagram as in Fig. 2a, for a third mode of operation of the suction device; Fig. 2d is a timing diagram as in Fig. 2a, for a fourth mode of operation of the suction device; Fig. 2e is a timing diagram as in Fig. 2a, for a fifth and sixth mode of operation of the suction device; Fig. 2f is a timing diagram as in Fig. 2a, for a seventh mode of operation of the suction device; Fig. 3 is a circuit diagram of the control unit used in the device of Fig. 1; Figs. 4a and b are schematic views showing the arrangement of magnets for sensing the movement of the handle of the smoke-generating equipment; and Fig. 5 a-c are schematic views showing different types of nozzles for the suction device according to the invention.

Description of preferred embodiments Fig. 1 shows a smoke suction device according to the invention, comprising a suction pump 1, the suction part, ie vacuum connection 1c, is connected via a filter part 2 to a suction nozzle 3.

A suction pump is suitably used as a compressed air-driven vacuum pump, a so-called compressed air-driven ejector, which operates on the principle that a large gas flow passes a choke, whereby just after the choke, where the vacuum a n «; ø now lO 15 20 25 30 35 518 424 - ~ fi =; ïí :: = 4 the connection lc is placed, a suction negative pressure is formed.

The advantage of using such a suction pump is that it has no moving parts, which reduces wear and thus the need for maintenance, and that it has a fast reaction response when activated. Furthermore, it is an advantage that such a pump can be made small, which facilitates its placement, as it does not necessarily have to stand on the floor but instead can be hung on the wall or ceiling, placed outside the operating room or the like. It is also an advantage that the pump is more energy efficient and has a lower noise and vibration level than previously used types of pumps.

The suction pump 1 has an inlet connection 1a for the inlet compressed air flow, an outgoing exhaust air connection 1b and an, already mentioned, suction vacuum connection 1c.

The outgoing exhaust air connection can advantageously be led away from the area which is sensitive from an infection control point of view via an exhaust air hose or exhaust air duct 6. This is also something that the National Board of Occupational Safety and Health finds desirable ("The National Board of Occupational Safety and Health's report l994: l"). For example, the exhaust duct may open outside the building. In this way, it is avoided that infectious particles that have not been taken up by the filter part are returned to the operating room.

The filter part 2 comprises at least one smoke-cleaning part 2a, which can advantageously be an ordinary and previously known smoke filter, and a liquid- and blood-separating part 2b. The latter part advantageously comprises a similarly known suction vessel. The filter part is connected so that the vacuum connection 1c of the suction pump is connected to the output connection of the smoke filter 2a, the input connection of the smoke filter is connected to the output connection of the suction vessel 2b and the input connection of the suction vessel via a sterile operating suction hose 4 is connected to the suction nozzle. suitably have non-interchangeable connections, for example through different diameters, in order to eliminate incorrect connection connection and thus 10 15 20 25 30 35 | | o. no 518 424 5 jande contagion risk. The sterile surgical suction hose 4 is advantageously of disposable type.

The filter part 2 is furthermore preferably a separate unit, for instance placed on a separate supporting and cohesive stand 5, in order to be able to be easily connected and disconnected. This is of great importance as it enables the removal of the filter part 2 from the operating room, which from the point of view of infection control is the most sensitive room. In this way, the filter part can easily be moved out to adjacent rooms during filter changes, emptying and cleaning of the suction vessel, etc.

The nozzle 3 can be a previously known so-called smoke extraction pipe which is applied to the hand tools of the smoke-generating equipment, for example diathermy tools of various designs, which in turn are connected to a diathermy device. The sterile surgical suction hose 4 may also be connected to various forms of speculum, monopolar and bipolar diathermy handles or hand-held suction devices.

Examples of how the suction nozzles can be designed are described in more detail below.

The compressed air flow to the suction pump 1 is led via one or more valves 7, 8 connected in parallel. These valves are advantageously electrically controlled solenoid valves, which are controlled by one or more control units 9. An example of such a control unit 9 is shown in Fig. 3.

The control unit comprises a function selector 11 with which different modes of operation of the device can be easily set. Furthermore, the control unit comprises inputs 12, 13 for sensing signals or other external signals, generators 14, 15 for generating square pulses and outputs 16, 17 for control signals for controlling the above-mentioned solenoid valves 7, 8.

Next, the various modes of operation with which the control unit in Fig. 3 can operate will be described in more detail.

If the function selector ll is set to the mode that activates the output lla, the "detection" function mode arises. In this position, a sensing signal is received via the input 12.

This signal can, for example, be generated by a power sensor which senses the power consumed by the smoke generating equipment. This signal is started if desired, which gives a time-selectable switch-on delay T1 (see Fig. 2a, b). a delay circuit 19 is desired which gives a time-selectable switch-off delay T2 (see Fig. 2a, b). the ranges for these two circuits can be wide. The signal is immediately gated out to the output 16 via the AND condition 20 which is fulfilled via the function selector 11 and then via a delay circuit 18. Then the Time OR condition 21 is restarted. 8 and the vacuum pump 1 is supplied with compressed air and activated immediately. A timing diagram showing the activation of a diathermy device in parallel with the activation of the suction device is shown in Fig. 2a. Essentially at the same time as the diathermy device is activated, or possibly after said delay T1, the suction device is activated. When the diathermy device is switched off, the suction device continues to be activated during said time period T2, which means that the suction device is already activated if the diathermy device is activated again shortly after the first use. This is an advantage as a smoke-generating diathermy sequence often involves a longer activation for a number of seconds followed by a number of corrective burns varying in time and length. If a burning, activation, has taken place, it is therefore probable that supplementary burning will take place shortly.

In a second function mode, "probability + sensing", the output llb of the function selector ll is activated. In this position, the device is self-activated with short intermittent suction shocks for a certain time after activation of the device due to sensing. This is achieved by sensing and activating the effect that the smoke-generating equipment consumes, as previously mentioned.

When the smoke extraction is stopped, a selectable delay circuit 23 starts for a time T3. During a selectable time, short, time-selectable, unstable pulses come from the 10 20 25 30 35. . The pulse generating generator 14 is now to be led out to the solenoid valve 8 via the AND condition 24 which is fulfilled by the function selector 11 and via the OR condition 21. The vacuum pump 1 thus receives compressed air and is activated. If a renewed firing is now performed, this is detected as above and gives a new activation. With this mode of operation, it is probable that an unstable pulse, and thus also a suction flow, exists during the renewed firing, which in principle means that the smoke extraction is established before the surgeon has had time to burn, while the suction hose is kept clean and effective infection protection is obtained. A timing diagram showing an example of this mode of operation is shown in Fig. 2b.

A third mode of operation, by selecting the output llf on the function selector ll. In "intermittent", this position is activated, the suction device is activated in short suction shocks, whereby the device is kept clean, the clot is kept away from the suction hose, and so on. This is achieved by shorting, time-selectable, unstable pulses from the pulse generator 15 to the solenoid valve 8 via the AND condition 25 which is fulfilled by the function selector 11 and then via the OR condition 21. Fig. 2c shows an exemplary time diagram for this mode of operation.

A fourth mode of operation, “intermittent + sensing”, means, as the name suggests, a combination of intermittent suction shocks and sensing of the diathermy device's power consumption. Because the suction device here is waiting in an intermittent pulsating function, there is a relatively high probability that the device is active when activation via the sensing takes place, at the same time as the device is kept clean. This mode is set by selecting output 11c on the function selector 11. In this mode the device is activated either by the sensed signal via an AND condition 26 and OR condition 28 or by a pulse transmitted from the pulse generator 15 via AND condition 27 and OR conditions 28. An example of how the suction device works together with a diathermy device is shown by means of a time diagram in Fig. 2d. a »o ~ n a. - -.-. - .von ~ ~ ~. wou- 10 15 20 25 30 35 518 424 8 A fifth mode of operation, is activated by selecting the output llg on the function selector ll. "Basic flow", This mode means that there is a continuous, reduced basic flow at all times. This is done by the signal via a drive stage 29 actuating the solenoid valve 7.

This basic flow is throttled by an adjusting member 30 (see Fig. 1) relative to the ordinary suction flow. Such a basic flow means that the suction device is kept clean at the same time as a certain suction activity already exists before the smoke-generating equipment is used. Advantageously, this mode of operation can be combined with, for example, the "sensing" function. An exemplary time diagram for "basic flow" combined with "sensing" is shown in Fig. 2e.

A sixth mode, "continuous", is obtained if the output llh is selected on the function selector ll. This position means that the suction device is activated at all times, which in some cases may be desirable. This mode of operation is likewise exemplified by a timing diagram in Fig. 2e.

A seventh mode, "external signal" is obtained by selecting output lle on the function selector ll. This mode of operation basically works as the “sensing” function.

An external signal is received via an input 31, a condition-controlled isolation stage 32 and a time delay circuit 33 for switch-on and switch-off delay to the OR condition 21.

The external signal can be, for example, from a signal generator built into the smoke-generating equipment, from a motion-sensing sensor (acceleration detector) in the handle of the smoke-generating equipment or a magnetic switch connected to the same handle. By sensing when the handle is moved, the suction device can be activated before the actual smoke-generating activation of the equipment takes place. The magnetic switch may be provided with a magnetic field sensing means in the diathermy handle for sensing magnets placed in, for example, the storage cup in which the diathermy handle is placed when not in use. Such a storage cup 35 with a magnet 36 connected thereto is shown in Fig. 4a. Alternatively, a mag- .. e - o .s vin-_ n. Uno 10 15 20 25 30 35 o o o | now 518 424 9 net by means of a tape strip or the like is attached directly to the patient, or other place where the surgeon usually puts down the handle. Such a taped magnet 37 is shown in Fig. 4b. Fig. 2f shows an exemplary time diagram for the mode of operation with sensing via the handle.

An eighth mode of operation of the suction device, which is set by selecting the output lld of the function selector 11, is a closed position. This position means that the suction device remains inactivated during firing, which may be desirable in particularly sensitive or deep surgery when, for example, brain tissue is at risk of being sucked in.

It should be emphasized, however, that the above-mentioned modes of operation of the control unit 9 are only examples of suitable modes of operation. Many similar variants of this are of course conceivable, as well as different combinations of modes of operation.

To make it easier for the operating staff to select the mode of operation, and to provide information on which mode of operation is currently used, a flow meter 10 (see Fig. 1) can advantageously be placed somewhere after the suction pump vacuum connection 1c, so that the size of the suction flow the time must be readable immediately.

The suction nozzles can be designed in many different ways. However, it is important that they are designed so that they end up close to the development of smoke, and do not pose a danger to the patient or an obstacle for the surgeon. Some examples of suitable designs of suction nozzles will now be reviewed.

On, for example, monopolar diathermy handles 40, the suction nozzle 41, as shown in Fig. 5a, can be designed so that it can be fastened along the handle with, for example, upper and lower clamps 42, 43. The nozzle is preferably made of a relatively rigid plastic material, and has at the upper end is provided with a connection 44 for connecting the operating suction hose 4. In the nozzle, a suction channel runs from the connection inside, which opens just above the burning part of the handle. For bipolar diathermy, or other equipment with tweezers-shaped handles 45, nozzles 46 with an inlet connection 47 and two suction orifices 49 are advantageously used, one at each handle leg, as shown in Fig. 5b. This type of nozzle is otherwise essentially designed as the above-mentioned, with upper and lower clamps 49, 50 for easy attachment to the handle.

It is also possible to instead attach nozzles 52 to wound hooks 51 or the like, as shown in Fig. 5c, so that nozzles are thus smaller in the way of the surgeon.

An embodiment of the invention has been described above. However, it should be emphasized that several variants are possible. For example, other types of filters are conceivable, the control unit can be designed differently and possibly also offer other functional alternatives, the nozzles can be designed differently, and so on. Such related variants must be considered to be within the scope of the present invention, as defined by the appended claims.

Characteristic of the invention is that it provides little work environment disturbance, efficient smoke evacuation, great freedom of choice in terms of mode of operation and good infection control safety.

It also offers good opportunities for flexible placement and can easily be designed to fit all existing smoke-generating surgical equipment.

Claims (7)

n. F '' www 10 15 20 25 30 35 Q asså 4124 u PATENTKRAV Smoke suction device for use with smoke-generating diathermy equipment, comprising a pump (1), a filter part (2), at least one suction nozzle (3), and sensing means for automatic activation of the device, the device being adapted to provide at least a certain suction flow even before the fact that the surgical equipment is used and thus generates smoke, and at the same time work with at least a reduced flow most of the time when the same equipment is in use but is not active, characterized in that the pump (1) is a pneumatic ejector without moving mechanical parts in which a gas flow passes a choke, whereby after the choke a suction negative pressure is formed to which the connection (1c) to the suction nozzle is connected and that the sensing means are adapted to activate the device when the surgical equipment is prepared for use. Smoke suction device according to claim 1, characterized in that the reduced flow takes place for a certain determined period of time after deactivation of the surgical equipment. Smoke suction device according to claim 1 or 2, characterized in that the reduced flow consists of a continuous suction flow with reduced flow rate. Smoke suction device according to claim 1 or 2, characterized in that the reduced flow consists of intermittent suction shocks. Smoke suction device according to one of the preceding claims, characterized in that the sensing means is arranged at the handle of the surgical equipment, in order to detect when the handle is moved. Smoke extraction device according to one of the preceding claims, characterized in that the filter part comprises a liquid- and blood-separating part (2b) and a smoke-cleaning part (2a). 518 4-24 / 2 Smoke extraction device according to any one of the preceding claims, characterized in that the filter means is easily detachable.