ITPR20130093A1 - SURGICAL ASPIRATOR AND A METHOD OF OPERATION - Google Patents

Description

DESCRIPTION

"Surgical aspirator and a method of operation"

The present invention relates to a surgical aspirator and a method of operation of said surgical aspirator.

A surgical aspirator is known in which there is a cannula for sucking organic fluids. This cannula is connected to a pump which is driven by an electric motor to suck said fluids.

During use, the operator places one end of said cannula in correspondence with said fluids to aspirate them. In general, during an operation, the operator can repeatedly approach the end of the cannula to the organic fluids to be aspirated. For practicality and convenience, the electric motor is always left running in order to avoid continuing to turn the engine on and off (to be avoided since this operation could involve repeated contact of an operator's hands with a button).

In this context, the technical task underlying the present invention is to propose a surgical aspirator and a method of operation thereof which allows to minimize energy consumption and noise. A further purpose of the present invention is to propose a surgical aspirator and a method of operation of the same that allows to increase the autonomy of operation of the same.

The specified technical task and the specified purposes are substantially achieved by a surgical aspirator and a method of operation thereof, comprising the technical characteristics set forth in one or more of the appended claims.

Further characteristics and advantages of the present invention will become clearer from the indicative, and therefore non-limiting, description of a preferred but not exclusive embodiment of a surgical aspirator and a method of operation thereof, as illustrated in the accompanying drawings in which figure 1 shows a schematic view of a constructive solution according to the present invention.

In the accompanying figures, the reference number 1 indicates a surgical aspirator. Surgical aspirators are suitable for withdrawing organic fluids such as blood or other from the body of living beings. This surgical aspirator comprises suction means 2 and an electric motor 3 which drives said suction means 2.

In the preferred solution the motor 3 is a brushless motor. Conveniently, the suction means 2 comprise a piston pump or a single-head diaphragm pump or a double-headed diaphragm pump or a peristaltic pump. The motor 3 is therefore operatively connected to said pump.

The aspirator 1 comprises a suction line 4 along which the suction means 2 generate a depression. By depression we mean a pressure lower than the atmospheric one. Conveniently, the aspirator 1 comprises a casing 90 which contains at least the motor 3, the pump, and a part of the suction line 4. The aspirator 1 also comprises a preferably flexible cannula 40 which extends externally to said casing 90. A first end of the cannula 40 comprises a suction section from the external environment. Conveniently along the suction line 4 there is a tank 9 in which the organic fluids drawn by the aspirator 1 are intended to accumulate.

Conveniently, the aspirator 1 comprises a pressure transducer 5 which provides information on the depression along the suction line 4. Said transducer 5 comprises a pressure-sensitive element located downstream of said cannula 40 with respect to the direction of advance of what is sucked along the suction line 4. This transducer 5 is advantageously placed downstream of the tank 9 with respect to the direction of advance of what is sucked along the suction line 4.

The aspirator 1 also comprises feedback control means 6 which control the rotation speed of the electric motor 3 as a function of a signal provided by the pressure transducer 5 (in particular as a function of the pressure measured by the transducer 5). The control means 6 are therefore able to control the electric motor 3 in real time as a function of the feedback signal supplied by the pressure transducer 5.

The control means 6 comprise means 60 for comparing the signal supplied by the transducer 5 with a predetermined threshold (a preset depression value). Conveniently, the predetermined threshold is adjustable by a user and stored by the aspirator 1. Preferably, but not necessarily, this predetermined threshold is between -0.15 and -0.25 bar, suitably it is equal to about -0.2 bar. The control means 6, at an increase in the depression detected by the transducer 5 from a value lower than a higher value of said predetermined threshold, determine an increase in the speed of the electric motor 3. The crossing of said predetermined threshold therefore determines an increase in the rotation speed of the motor 3. The increase in depression accompanies the passage of the aspirator 1 from an inoperative situation in which it takes practically only air to an operating situation in which it takes a greater amount of material (e.g. organic fluids). Consequently, the electric motor 3 increases its own rotation speed to make more power available. An increase in depression means a reduction in pressure. By reducing the vacuum we mean an increase in pressure.

The control means 6 to a reduction of the depression detected by the transducer 5 from a higher value to a lower value with respect to said predetermined threshold determine a speed reduction of the electric motor 3 (in the limit the motor 3 could even stop even if it preferably remains in rotation). The decrease in depression accompanies the passage of the aspirator 1 from an operating situation in which it withdraws a greater amount of material (for example organic fluids) to an inoperative situation in which it essentially withdraws only air. In fact, when the liquid-solid material to be sucked along the suction line 4 fails, the depression induced by the suction means 2 decreases. Consequently, the electric motor 3 decreases its rotation speed to reduce the noise generated by it and to reduce consumption (as well as to increase its autonomy if it runs on batteries and is not connected to the electrical network). In fact, in this situation it is not necessary to move the engine at high speeds. The control means 6 comprise a control microswitch (which conveniently manages the rotation revolutions of the motor 3 and the signal from the transducer 5).

Conveniently, the aspirator 1 comprises an air inlet valve 7 in said suction line 4. When a desired depression is exceeded, the valve 7 puts said suction line 4 in communication with the external environment to prevent the achievement of a depression lower than the desired one. In fact, the opening of the valve 7 allows the entry along the line 4 for the intake of external air. The opening and closing of said valve 7 is controlled by the control means 6 (in particular by the micro).

Conveniently, the aspirator 1 comprises a user interface 80 comprising means for adjusting the desired depression (for example, these adjustment means could include a manual selector). Conveniently, the aspirator 1 (in particular the control means 6) can comprise storage means in which the desired depression value is stored. This value of the desired depression is preferably between -0.1 bar and -0.9 bar. This value of the desired depression is adjustable by a user. In particular, it is adjustable between -0.1 bar and -0.9 bar.

The control means 6, upon exceeding a predetermined time interval in which the adjustment means remain unchanged, cause a slowdown in the rotation speed of the electric motor 3 and the achievement of an operating mode in which said transducer 5 still detects said desired depression. . Conveniently this happens only if the motor 3 is at full speed (in this case the motor 3 advantageously rotates at a speed of between 2500 and 3500 rpm, preferably rotates at about 3000 rpm). In practice, after a time interval in which the adjustment means remain unchanged, the aspirator 1 spontaneously evolves towards an operating mode in which it is in any case able to guarantee the desired depression by reducing the entry of external air through said valve 7. This arrangement also makes it possible to reduce energy and noise consumption with the same result. The slowing down of the rotation speed of the motor 3 advantageously occurs linearly (with respect to time).

Conveniently, the aspirator 1 can include a power supply battery (which guarantees the operation of the motor 3). Advantageously, the aspirator 1 can be transportable. For example, the aspirator 1 could be wheeled. The aspirator 1 can therefore be an emergency aspirator (for example to be used for first aid on ambulances and the like).

Conveniently, the aspirator 1 can comprise means of connection to the electrical network (for example 110-220V).

The object of the present invention is a method of operation of a surgical aspirator. Conveniently, this aspirator 1 comprises one or more of the characteristics described above. Said aspirator 1 comprises the steps of:

-generating a vacuum along a suction line 4 by means of suction means 2 driven by an electric motor 3;

- obtaining information relating to the depression in said suction line 4 by means of a pressure transducer 5 (this transducer 5 measures the depression in a predetermined area of the suction line 4).

Conveniently, said method comprises the step of adjusting the rotation speed of the electric motor 3 as a function of a pressure signal supplied by the transducer 5. The system is therefore controlled in feedback. The variable which controls the revolutions of the motor 3 is the depression which is generated at a predetermined point of the suction line 4. The step of adjusting the rotation speed of the electric motor 3 as a function of a pressure signal supplied by the transducer 5 comprises the step of carrying out this adjustment in real time. The step of adjusting the rotation speed of the electric motor 3 comprises the step of performing a comparison between the pressure signal supplied by the transducer 5 with a predetermined threshold (exemplary values of said predetermined threshold have been previously indicated); a passage of the depression detected by the transducer 5 from a lower value to a higher value of said predetermined threshold determines an increase in the speed of the electric motor 3; a passage of the depression detected by the transducer 5 from a higher value to a lower value of said predetermined threshold determines a speed reduction of the electric motor 3. In fact, this signals that a rotation of the electric motor 3 at high speeds is not necessary since the aspirator 1 is not actually sucking in organic fluids (in a particular solution the electric motor 3 could also stop completely, but preferably continues to spin). If the comparison between the pressure signal supplied by the transducer 5 and said predetermined threshold indicates the detection, by the transducer 5, of a depression higher than said predetermined threshold, the electric motor 3 assumes a first operating mode. The signal 5 provided by the transducer 5 therefore signals that the aspirator 1 is in use. Conveniently, in the first operating mode, the electric motor 3 rotates at a rotation speed of between 2500 and 3500 rpm, preferably rotates at a speed of approximately 3000 rpm.

If the comparison between the pressure signal supplied by the transducer 5 and said predetermined threshold indicates the detection by the transducer 5 of a depression lower than said preset threshold, the electric motor 3 assumes a second operating mode in which it rotates at a lower speed with respect to said first operating mode.

Conveniently, the method includes the steps of:

- selecting by regulating means a desired depression in a predetermined area of the suction line 4, said regulating means forming part of a user interface 80;

- putting the suction line in communication with the external environment by means of a valve 7 in order to maintain the desired level of depression; - slowing down the rotation speed of the electric motor 3 reaching a new operating mode in which said desired depression is in any case ensured.

The step of slowing down the speed of rotation occurring after the adjustment means have not been modified for a period exceeding a predetermined time interval. This predetermined time interval could be adjustable. As previously indicated, in this way it is still possible to reduce energy consumption and noise without penalizing the depression obtained.

The step of slowing down the speed of rotation occurring if the electric motor 3 is in said first operating mode.

The invention has multiple advantages. A first advantage is linked to the fact that it allows to reduce energy consumption. A further important advantage is the reduction of noise at times when the maximum operating power is not required. Another important advantage is linked to the increase in autonomy when this vacuum cleaner is powered by batteries.

The invention thus conceived is susceptible of numerous modifications and variations, all falling within the scope of the inventive concept that characterizes it. Furthermore, all the details can be replaced by other technically equivalent elements. In practice, all the materials used, as well as the dimensions, may be any according to requirements.

Claims (10)

CLAIMS 1. Surgical aspirator comprising: - suction means (2); -an electric motor (3) which drives said suction means (2); -a suction line (4) along which the suction means (2) generate a vacuum; characterized by the fact of understanding: -a pressure transducer (5) which provides information on the depression along the suction line (4); - feedback control means (6) which control the rotation speed of the electric motor (3) as a function of a signal supplied by the pressure transducer (5). 2. Aspirator according to claim 1, characterized in that the control means (6) comprise means (60) for comparing the signal supplied by the transducer (5) with a predetermined threshold; the means (6) for controlling an increase in the depression detected by the transducer (5) from a lower value to a higher value of said predetermined threshold, causing an increase in the speed of the electric motor (3); the control means (6) to reduce the depression detected by the transducer (5) from a higher value to a lower value than said predetermined threshold, causing a speed reduction of the electric motor (3). 3. Aspirator according to claim 1 or 2, characterized in that it comprises: - a valve (7) for air inlet into the suction line (4), said valve (7), when a desired depression is exceeded, puts said suction line (4) in communication with the external environment to prevent the achievement of a lower than desired depression; - a user interface (80) comprising means for adjusting the desired depression; the control means (6), upon exceeding a time interval in which the adjustment means remain unchanged, causing a slowing down of the rotation speed of the electric motor (3) and reaching an operating mode in which said transducer (5) still detects said desired depression. 4. Aspirator according to any one of the preceding claims, characterized in that said motor (3) is a brushless motor, said suction means (2) comprising a piston pump or a single-head diaphragm pump or a diaphragm pump double head or a peristaltic pump. 5. Aspirator according to any one of the preceding claims, characterized in that said suction line (4) comprises a cannula (40), said transducer being placed downstream of the cannula (40). 6. Method of operation of a surgical aspirator comprising the steps of: -generating a vacuum along a suction line (4) by means of suction means (2) driven by an electric motor (3); - measuring the depression in said suction line (4) by means of a transducer (5); characterized in that it regulates the rotation speed of the electric motor (3) as a function of a pressure signal supplied by the transducer (5). Method according to claim 6, characterized in that the step of adjusting the rotation speed of the electric motor (3) comprises the step of making a comparison between the pressure signal supplied by the transducer (5) with a predetermined threshold; a passage of the depression detected by the transducer (5) from a lower value to an upper value of said predetermined threshold causing an increase in the speed of the electric motor (3); a passage of the depression detected by the transducer (5) from a higher value to a lower value of said predetermined threshold causing a reduction in the speed of the electric motor (3). 8. Method according to claim 6 or 7, characterized in that: - if the comparison between the pressure signal supplied by the transducer (5) and said predetermined threshold indicates the detection, by the transducer (5), of a higher vacuum at said pre-set threshold the electric motor (3) assumes a first operating mode; - if the comparison between the pressure signal supplied by the transducer (5) and said predetermined threshold indicates the detection by the transducer (5) of a depression lower than said preset threshold, the electric motor (3) assumes a second operating mode in which it rotates at a lower speed than said first operating mode. 9. Method according to claim 6 or 7 or 8, characterized in that it comprises the steps of: - selecting by means of adjustment means a desired depression in a predetermined area of the suction line (4), said adjustment means forming part of a user interface (80); - putting the suction line (4) in communication with the external environment by means of a valve (7) in order to maintain the desired depression level; - slow down the rotation speed of the electric motor (3) reaching a new operating mode in which said desired depression is in any case ensured, the step of slowing down the rotation speed occurring after the adjustment means have not been modified for a longer period at a predetermined time interval. Method according to claim 9 when it depends on claim 8, characterized in that the step of slowing down the speed of rotation occurs if the electric motor (3) is in said first operating mode.