RU2032425C1 - Automatic apparatus for sucking off liquid - Google Patents

Abstract

FIELD: medical engineering. SUBSTANCE: this apparatus includes suction unit receiving vessel having detachable cover consisting of upper portion 4 and lower portion 5 between which is positioned flexible membrane 6 whose rigidity regulator is combined with pneumatic valve. Cover upper portion 4 has openings 10 for communicating chamber disposed above membrane with atmosphere. In cover lower portion are disposed inlet connection 22, outlet connection 13 and safety valve 28. Inlet connection 22 is fitted into opening which is inclined relative to base. Inner end portion of this inlet connection communicates with curved receiving pipe 25 having branch 26 in its upper portion and inner diameter exceeding inner diameter of inlet connection 22. Outlet connection 13 is fitted into opening which communicates with chamber disposed under membrane and receiving vessel. Safety valve 28 is located in recess which communicates with outlet passage which incorporates aerodynamic source of acoustic waves 34. Disposed in lower portion of cover is adjustable emergency vacuum relief valve 36 and additional aerodynamic source of acoustic waves 37 tuned to different frequency. EFFECT: more sophisticated design. 2 cl, 1 dwg

Description

 The invention relates to medical equipment, in particular to automatic blood suction used in surgery, as well as in other areas of medicine associated with the suction of fluids from body cavities.

 Known surgical aspirator containing a vacuum source, blood sampling, connecting lines and a receiving tank with a lid, which in turn contains a housing, inlet and outlet fittings, a safety valve.

 The disadvantage of this design of the aspirator is the inability to reuse the aspirated blood due to increased trauma that occurs due to the lack of automatic maintenance and regulation of the suction mode, as well as a system for preventing blood spatter.

 A vacuum medical bottle is also known, where the reduction of blood trauma occurs due to the use of a system for reducing blood foaming in a receiving container. Reducing blood foaming is achieved by separating air bubbles entering the aspirated blood when the inlet of the blood intake is not completely submerged directly at the entrance to the receiving container.

 This design of the aspirator still does not completely avoid the foaming of blood at its low level in the receiving tank and at the maximum allowable vacuum values during the suction process. In this device, it is not possible to maintain a constant suction mode when there are obstacles at the entrance to the suction.

 The closest in technical essence to the proposed device is an apparatus for collecting body fluids, which contains a vacuum source, a fluid intake, connecting lines, a receiving tank with inlet and outlet fittings installed in the lid, a safety valve and an automatic suction mode control unit, including controlled air a valve and a mechanical pressure sensor, the membrane of which has a stiffness regulator and is connected to a switch, the fluid intake being connected to the input nym nipple and the outlet nipple through a tee connected with a closed cavity pressure sensor and the vacuum source, which is implemented through the power switch, a membrane-bound probe. The presence of an automatic unit in this device allows you to automatically weaken the suction vacuum in the event of obstacles at the entrance to the apparatus, maintaining a constant suction mode.

 The disadvantage of this device is that the automatic control unit is a mechanoelectric design, which increases the response time of the automation, thereby preserving significant fluctuations in the vacuum in the receiving tank. The safety valve, which prevents overflow of the receiving tank, is installed with the possibility of blocking the supply of vacuum to the receiving tank at the maximum liquid level in it. Such a safety valve installation scheme can lead to suction fluid entering the pneumatic line when it is skewed, or to jam in the closed position due to suction from the vacuum system. In addition, the absence of a sound alarm in the suction when filling the receiving tank forces the personnel to constantly monitor the liquid level in the receiving tank, unreasonably diverting their attention.

 The aim of the invention is the elimination of blood injury during suction due to the achievement of the optimal absorption mode due to the automation of this process.

 This goal is achieved by the fact that the housing cover of the receiving container is made detachable and contains upper and lower parts, between which an elastic membrane is installed, the stiffness regulator of which is integrated with the air valve, and the upper part of the cover body has openings for the camera to communicate above the membrane with the atmosphere, and at the bottom there are inlet and outlet fittings and a safety valve, and the inlet fitting is installed in an opening made with an inclination to the base, and is connected to the receiving tube by the inner end made curved with a lead in the upper part and an inner diameter greater than the inner diameter of the inlet fitting, and the outlet fitting is installed in the hole, which is in communication with the camera under the membrane and the internal volume of the receiving tank, and the safety valve is installed in the recess of the lower part of the lid with a channel for entering the atmosphere, which contains an aerodynamic sound source. In addition, in the lower part of the lid body there is a second emergency adjustable rarefaction relief valve exceeding the maximum permissible values, and a second aerodynamic sound source tuned to a different tonality.

Thus, compared with the prototype, the proposed automatic device for suctioning liquid has the following significant distinguishing features:
the air valve does not have an electric actuator and is combined with a membrane stiffness regulator, which is installed in the detachable housing of the cover of the receiving tank;
the receiving tube of the receiving tank is made curved with an inclination to the base and contains a lead in the upper part for applying a working vacuum and removal of air fractions isolated from the suction blood;
the safety valve is installed with the possibility in the open state to reduce the working vacuum of the receiving tank due to suction of atmospheric air;
the presence of an audible alarm when filling the receiving tank.

 The combination of an air valve with a membrane stiffness regulator of a mechanical pressure sensor makes it possible to make the suction device more compact and exclude the electrical part (switch, air valve electric wire) from the automatic process. This achieves a decrease in the response time of the system with deviations from the set mode, which in turn leads to a decrease in rarefaction pulsations in the receiving tank to a minimum, eliminating accordingly the injury from this factor.

 The original design of the receiving tube of the receiving tank allows, firstly, due to the different internal diameters of the inlet fitting and the receiving tube to reduce the speed of blood flow in the area behind the inlet fitting, and secondly, due to the inclination of the receiving tube to the base to reduce the inertia of the blood when it falls into the receiving tank , i.e. to achieve its smooth runoff along the walls of this receiving tube and, thirdly, due to the presence of a lead in the upper part, to separate the air fractions from the suction blood in the tube itself, removing them along this knee. All this will allow to eliminate the foaming and spraying of blood in the receiving tank due to the separation of air fractions from the blood portions in the initial sections and ensuring smooth drainage of blood to the bottom of the receiving tank.

 Installing a safety valve with the ability to open to start external or atmospheric air in the receiving tank, and not block the vacuum supply, as in the prototype, it is guaranteed to stop the suction process without possible undesirable effects, such as jamming and misalignment of the valve. Such highly reliable operation of the safety valve in the proposed design will ultimately protect against undesirable phenomena that cause additional blood injury. The presence of an audible alarm will allow you to timely inform about the filling of the receiving tank, making the suction process fully automatic.

 The elimination of blood trauma due to the automation of the suction process during surgical operations will allow the patient to become a donor for himself, minimizing or eliminating the need for extraneous donor blood. This approach leads to the resolution of problems associated with transfusion of foreign blood, the central of which is the likelihood of contracting AIDS. In addition, automatic suction, which is implemented in the proposed device, may in itself become a source of donated blood, followed by, if necessary, its processing.

 The drawing shows the proposed automatic device for suctioning a liquid.

 The device comprises a receiving container 1 and a detachable cover 2. To the receiving container, the cover is fastened by means of latches 3, which pull the upper part 4 of the cover and the lower part 5 with the membrane 6 laid between them to the neck of the receiving container. To increase the stiffness, the bottom membrane is spring-loaded with a spring 7. The latches are fixed on the upper part of the cover and are inserted into the lapels of the clamp 8, covering the neck of the receiving tank. In this case, the lower part of the lid fits tightly on the neck, and the membrane is tightly clamped between the upper and lower parts of the lid, dividing the inner space of the lid into two air chambers. The chamber 9 above the membrane through the openings 10 in the lid communicates with the atmosphere, and the chamber 11 under the membrane through the channel 12 and the outlet fitting 13 communicates with both the vacuum source 14 and through the hole 15 with the internal volume of the receiving tank. A channel 16 is also brought into the hole 15, communicating with a vacuum gauge 17 installed in the lower part of the lid. A vacuum gauge is necessary for visual monitoring of the working vacuum during its regulation and during operation. The role of the air valve, combined with a membrane stiffness regulator, is performed by a nozzle 18 installed in the central part of the membrane and an adjusting screw 19, the conical part of which overlaps the hole 20 of this nozzle. The adjusting screw is screwed into the upper part of the lid body with the possibility of fixing it in the position set after adjustment by means of lock nut 21. The inlet fitting 22 is fixed in the lower part of the lid body and is joined by a flexible line 23 with a blood sampling 24. A receiving tube 25 is fixed on the inner end of the inlet fitting with lead 26 and extension hose 27, lowered to the bottom of the receiving tank. The safety valve 28 is also fixed in the lower part of the cover body and contains a seat 29, a locking element 30, a stem 31 and a float 32, and the space above the valve through the channel 33 communicates with the atmosphere, and a whistle 34 is installed in this channel, giving an audible signal when a flow occurs air through channel 33 at the time of opening of the safety valve.

 In addition, in the lower part of the lid body in channel 35, a second emergency adjustable valve 36 for vacuum relief, exceeding the maximum permissible values, and a second sound generator 37, tuned to a different tone and issuing an audible signal when air flow occurs through channel 35 at the time of opening the emergency valve, are installed.

 Automatic device for suctioning liquid works as follows.

 After fixing the clamp 8 on the neck of the receiving tank 1, installing the lower part 5 of the lid on the receiving tank, installing the membrane 6 and the upper part 4 of the lid and then tightening them by means of latches 3, the line 23 with blood sampling 24 is connected to the inlet 22 and to the outlet 13 line from the source of rarefaction 14. Turn on the vacuum compressor and the adjusting screw 19 when the inlet of the blood intake is not fully pinched, the membrane stiffness is changed corresponding to the required value of the supported rarefaction Nia in the receptacle. The stiffness of the membrane and, accordingly, the value of the regulated vacuum is higher when tightening the screw, lower when unscrewing. The set vacuum value is controlled by a vacuum gauge 17, and then the adjusting screw is fixed in the set position with lock nut 21. The suction device is ready for operation.

 When the blood intake is immersed in a liquid, a resistance arises in the input line, which contributes to an increase in vacuum in the receiving tank. At rarefaction values higher than the adjusted one, the membrane shifts, the nozzle opening opens and the increased rarefaction in the receiving tank is compensated by the atmospheric air introduced through openings 10 and 20. After such compensation, the membrane is shifted back due to its elasticity and the action of the spring 7. At the same time, the nozzle opening is blocked by the conical part of the adjustment screw, stopping the flow of atmospheric air into the receiving tank. Thus, rarefaction fluctuations that occur during operation with the aspirator are damped by the supply of atmospheric air to the internal volume of the receiving tank, excluding blood injury caused by uncompensated refluxes of the working vacuum.

 The exception of blood injury during movement along the highway and in the receiving tank of the aspirator is achieved as follows. Under the action of a constant value of the vacuum applied to the inlet of the lead 26 of the receiving tube, the blood is drawn into the receiving line and moves at a constant speed. After passing the inlet fitting, a portion of blood enters the receiving tube. At the same time, its speed decreases sharply, since the inner diameter of the receiving tube is larger than the internal diameter of the nozzle, the smooth bending of the receiving tube and the inclination of its inlet end to the base leads to a decrease in the inertia of the blood movement, which reduces the rate of blood falling into the receiving capacity due to the smooth draining of blood along the walls of the tube.

 In the proposed device, a vacuum is applied to the input line through the lead of the receiving tube. This scheme of summing up the vacuum allows to exclude both spatter and foaming of blood in the receiving tank. Spraying is eliminated by the presence of an extension tube through which blood flows to the bottom of the receiving tank, and foaming due to the separation of air bubbles from the blood mass directly in the upper part of the receiving tube and removing them by the lead. So, a portion of blood flows through the inlet tube to the bottom of the receiving tank through an extension tube. Since the lead of the receiving tube from the place of docking with this tube has an ascending knee, the whole blood will not be able to be captured by the air stream and be discharged through the lead, but will fall to the bottom of the receiving tank under the influence of gravity. It is practically impossible to avoid air entrainment at the entrance to the blood intake, therefore, the resulting air-blood mixture will move along the inlet line, inlet fitting and receiving tube. Due to the fact that air bubbles are lighter than the mass of whole blood, they will not be able to get through the tube into the receiving tank, but will accumulate here in the receiving tube, rising up. When they reach the opening of the outlet tube, the bubbles will be trapped in a stream of air and discharged through the lead.

 After the receiving container is filled and the blood level reaches the maximum value determined by the position of the float, the latter through the rod 31 will raise the locking element 30 and thereby seal the receiving container. The atmospheric air entering through channel 33 will compensate for the operating vacuum, which in this case will drop sharply. This will stop the flow of blood into the receiving tank, excluding its overflow. When the air flow through the channel 33 of the safety valve appears, the sound source 34 installed in it will generate a signal notifying that the receiving tank is full. In the event of an unexpected failure in the operation of the suction caused either by theoretically possible mechanical breakdown of parts or jamming of the drainage holes, excessive vacuum in the receiving tank will be reduced by opening the second emergency valve 36. The resulting air flow through channel 35 will excite the second sound generator 37 installed in this channel. The resulting signal, which has its own tonality, will immediately report on the malfunctions that have occurred, and the discharge of atmospheric air into the receiving tank through the emergency channel will not allow the suction mode to go beyond the permissible values.

 Thus, the principles embodied in the automatic device for suctioning the liquid with their specific solution make it possible to exclude blood injury during suction and to obtain a non-traumatic suction of blood. This is achieved by automatically adjusting the suction mode, as well as automatically maintaining it at the set level. Blood in the receiving container does not spatter or foam, since it flows through a curved tube, and air is separated from the blood directly at the entrance to the receiving container. The installation of safety and emergency valves in the channels connected with the atmosphere maximizes the probability of failure-free operation of the suction device and relieves in the case of a safety valve of undesirable malfunctions caused by jamming and distortion of the shut-off element during valve operation. The air flow generated when the valve is triggered is used to generate sound vibrations leading to a sound signal. The frequency of sound signals may vary. In addition, the sound signal in the channel of the safety valve can be used as a signal characterizing the achievement of a certain amount of blood in the receiving tank.You can set this volume either by changing the length of the stem of the safety valve or by changing the volume of the receiving tank.

Claims (2)

 1. AUTOMATIC DEVICE FOR LIQUID EXHAUST, containing a vacuum source, a liquid intake, connecting lines, a receiving tank with inlet and outlet fittings installed in the cover, a safety valve and an automatic suction control unit, including a controlled air valve and a mechanical pressure sensor, whose membrane has a stiffness regulator and is connected to the switch, and the fluid intake is connected to the inlet fitting, and the outlet fitting is connected to the closed strip through a tee a pressure sensor and a vacuum source, in the power supply circuit of which a switch is connected, connected to the sensor membrane, characterized in that the housing of the cover of the receiving container is detachable and contains upper and lower parts, between which there is an elastic membrane of the pressure sensor, the stiffness controller of which is combined with the air a valve, and the upper part of the lid body has openings for communication of the chamber above the membrane with the atmosphere, the inlet and outlet fittings and a safety valve are installed in the lower part of pus of the cover, the inlet fitting is installed in an inclined hole and the inner end is connected to a receiving tube made curved with a lead in the upper part and an inner diameter greater than the inner diameter of the inlet fitting, and the outlet fitting is installed in the hole that has a communication with the camera under the membrane and the inner the volume of the receiving tank, and the safety valve is installed in the recess associated with the channel to exit into the atmosphere in which the aerodynamic sound source is installed.  2. The device according to claim 1, characterized in that an emergency adjustable rarefaction relief valve and an additional aerodynamic sound source configured for a different tonality are installed in the lower part of the lid body.