RU7876U1 - PNEUMO-CONTROLLED VACUUM PULSE FORMER - Google Patents

Abstract

1. A pneumatically controlled vacuum pulse generator for a breast pump, comprising a pneumatic vacuum-atmosphere key located in the housing, made with the possibility of connecting to a vacuum pulse regulator and a milk pump milk collector, characterized in that the pneumatic vacuum-atmosphere key consists of two replaceable elastic nozzles and the mechanism of their clamping, which contains a pneumatic pusher with a pressing element, a spring-loaded bracket having a through groove on the side wall, which is mounted on the rod, nom in the support with the possibility of reciprocating movement in the direction of the pressure member, and a rod mounted on the housing and passing through the through groove in the bracket, while one nozzle is placed on the shelf of the bracket under the pressure member, the other nozzle is on the other shelf of the bracket under the said rod moreover, the nozzles are made with the possibility of connecting at one end to the milk collector, and at the other ends to the vacuum pulse regulator and to the atmosphere, respectively. 2. The shaper according to claim 1, characterized in that it is equipped with a vacuum reservoir connected to a pipe configured to connect a vacuum pulse to the regulator.

Description

FOLLOWING SCHULSES VACUUM DYA MILK PUMP

The utility model relates to the field of Kyoto and is intended for use in medicine, namely, as part of the DNYA devices for the removal of milk from w @ nvj (breast pumps).

P1 is known to be a pneumatically controlled forwarder of vacuum pulses in a device for pumping milk / I /, functionally independent, and made in the interior of a tightly fixed rotating plate with pneumatic holes tightly adjacent to each other. The coincidence of the pneumatic ducts ensures the formation of vacuum pulses, the duration of which is determined by the rotation speed of one of the plates, and the amplitude is set by the vacuum regulator. The known device can be used sequentially by several patients. At the same time, microfyaor from the milk of one patient, falling into the pneumatic passages of the former ShBB vacuum shaper in the form of aerosol particles, can be transmitted to the patient afterwards, as a result of which infection of users with such a device is possible.

W 6 A6I MI / 00

Known pneumatic control pulse shaper saicyum, used in the device EOM-1/2 / for sucking milk in women, made in the form of a valve for regulating the duration of a vacuum pulse controlled by a cam mechanism. In this case, the valve inlet is connected through the regulator of the amplitude of the vacuum pulses to the vacuum source. The known device, the vacuum shaper, is attached to the milk collector through a filter, usually a cotton filter, which does not guarantee the absence of aerosol particles of milk in the shaper and thereby reduces its efficiency. In addition, a significant loss of vacuum on the filter.

Known pneumatically controlled vacuum pulse shaper in a device for expressing milk in women / 3 /, made on membrane elements of pneumatic automation, which includes a vacuum pulse regulator with a vacuum-atmosphere key giving connections to the milk collector of the breast pump and atmosphere, which controls the amplitude and duration of vacuum pulses - a source of adjustable vacuum. Vacuum pulses generated by the shaper are supplied via a pneumatic line through a biological filter to the milk collector and the pad applied to the female breast, while the vacuum-atmosphere key controls the supply of vacuum pulses, which ensures that the mammary gland undergoes reduced and atmospheric pressure in the Cyclic mode. However, the biological filter, which is made with a cotton filter, does not guarantee reliable protection of the pneumatic line and the cshler of the membrane elements of the pneumatic automatics against the ingress of pathogenic microflora from the patient’s milk, which can cause infection in subsequent patients. In addition, the elements of the day automation are basically not adapted to the sterilization process, which affects the operational characteristics of the breast pump as a whole. Known pneumatic shaper YMShCH LOBS vacuum for breast pump is selected as the closest analogue of the claimed utility model. A disadvantage of the known vacuum pulse shaper is unsatisfactory performance with respect to the possibility of infection of patients, the inability to sterilize the pneumatic delivery paths. The problem solved by the utility model is to improve operational characteristics, reduce the risk of infection and improve the sterilization conditions of the device. The technical result achieved by the utility model consists in the fact that the pneumatic paths for the formation and delivery of the valuum pulses along which the movement of aerosol particles of milk in the directions from the patient to the patient is possible are easily replaceable and easily sterilized by Iv1nmi, which virtually eliminates infection of one patient from another through the apparatus. The problem is solved in that, in the well-known pneumatically controlled vacuum pulse generator for a breast pump, including a pneumatic controlled vacuum-pressure switch located in the housing, configured to connect to a vacuum spool regulator and to a milk pump milk collector, in accordance with a utility model, the pneumatic controlled vacuum key consists of a vacuum of two interchangeable elastic pipes and a clamping mechanism, which contains a pneumatic pusher with pressure

an element, a bolted bracket having a through groove on the side wall, which is mounted on a rod mounted in a support with the possibility of reciprocating movement in the direction of the pressure member, and a rod mounted on the housing and passing through the through groove in the bracket, while one pipe placed on the shelf of the bracket under the pressure element, another pipe on the other shelf of the bracket under the said rod, hiding the pipes are made with the possibility of connecting one end to the milk collection, and the other ends to the pulse regulator vacuum and to at1kusphere, respectively.

In addition, the vacuum shaper for coca milk pumps is equipped with a vacuum reservoir connected to a nozzle configured to be connected to a vacuum pulse regulator.

The essence of the utility model is illustrated in FIG. 1, which shows a driver circuit as part of a functional diagram for connecting key elements, and FIG. 2, which shows a pneumatically controlled vacuum-atmosphere key in two extreme working positions of a pressure element (front view A, B, view side - B, D).

the vacuum filler shaker contains interchangeable nozzles I and 2, which are connected at one end by means of the interchangeable pneumatic conduit 3 to the milk assembly i plate on the nipple (Fig. 1). The other end of the pipe I is connected to the atmosphere, and the pipe 2 is a vacuum reservoir 4, which is installed additionally, and through it - with a vacuum pulse regulator (source of controlled vacuum) - not shown in Fig. 1. It is also possible to directly connect the pipe 2 to the vacuum regulator. Branch pipes I and 2 interact with

the HZ clamping mechanism, which contains a pneumatic actuator pusher 5, is connected to the pneumatic amp generator (not shown in Fig. 1), which controls its operation. The pusher is mounted on the device. The elastic pipe I is placed on one shelf of the bracket 6, and the second pipe 2 on the other shelf of the bracket 6, which is connected with the spring 7 (spring loaded) i is rigidly mounted on the rod 8, mounted in the support 9 with the possibility of movement. The rod 10 interacts with the bracket 6, passing into the bracket through the through groove II in its wall, and the rod 10 in its extreme positions in the through groove II provides either clamping of the pipe 2 npi against the shelf 13 of the bracket 6, or clamping the pipe I when lowering the bracket 6 (due to the movement of the rod 8 in the channel 14) and the interaction of the shelf 12 with the pressure element 15 of the pusher 5 (Fig, 2). The rod 10 is rigidly fixed to the breast pump housing. The pressure element 15 is made movable and is controlled by the pusher 5. The pressure element 15 and the rod 8 are mounted coaxially and make mutual reciprocating motion. The connection of nozzles I and 2 to the atmosphere and to the vacuum pulse regulator (or vacuum reservoir 4) can be reversed, i.e. the end of pipe I can be connected to a vacuum pulse regulator, and the end of pipe 2 to the atmosphere. In this case, the phase of the vacuum pulses acting on the milk collection and the lining changes by 180.

Chevmo-controlled pulse shaper vacuum operates as follows. The pulse former is launched by an external pneumatic pulse generator through a pneumatic pusher 5. In the absence of a control air pressure sensor, the pressure element 15 is removed and the pipe I is not pinched. But in the initial position, the bracket 6 is in its upper position, the rod S is extended and the pipe 2 is pressed by the rod 10 to the shelf 13 of the bracket 6, it is clamped and the pneumoproode 3 is disconnected from the vacuum source. Milk collection and the lining on the nipple of the breast pump are under atmospheric pressure ($ ig. 1). When applying the pneumatic control pulse from the pneumatic pulse generator to the pusher 5, the pressure member 15 extends, presses the pipe I to the shelf 12 of the bracket 6 and pinches it, disconnects it from the atmosphere (d.2-B, D). After clamping the nozzle I, the clamp 6 is lowered, the rod 10 is in the extreme position and releases the nozzle 2, which opens to supply vacuum imp / ls to the milk collector and the lining through the pneumatic pipe 3. The rod is released through the channel 14, while the spring 7 is pressed, After the pneumatic pulse ends the control, the pressure element 15 is retracted into the pusher 5, at the same time, the spring 7 lifts the bracket b in the direction of the pressure element 15, and the rod 10 begins to compress the pipe 2, the compression of which ends the vacuum needle in the pneumatic conduit 3. C erzhen 10 comes to its outermost position limited by a slot in the bracket 6 II, I branch pipe is opened, a compressed air line 3 is set at atmospheric pressure. With the supply of the next pneumatic control pulse, the cycle is repeated (Sfig, 2-A, B, fig. 2-B, G).

The air in the system, with an open pipe, moves FROM the atmosphere into the pneumatic pipe 3, and with an open pipe 2 (vacuum pulse) - from the pneumatic pipe 3 in the direction of the vacuum source, including the vacuum reservoir 4. Therefore, aerosol particles of milk falling into air line 3 or nozzles 1,2, cannot get back into the milk collector with air flow, which excludes infection of patients under the condition of sterilization or replacement of elastic nozzles 1,2 in case of collective use of the breast pump.

A vacuum reservoir 4 connected to the nozzle, which connects to the vacuum pulse regulator, allows the latter to operate in a more economical mode, reduces vacuum consumption and reduces the time required to increase the vacuum pulses (the steepness of the front of the pulse), which positively affects the formation of the milk flow reflex in a patient using a breast pump,

In addition, the reservoir 4 has the functions of a buffer capacity, since inaccurate handling of the apparatus may cause direct milk to enter the nozzles 1,2 and the reservoir 4, the vacuum pulse regulator will not be damaged, and the mentioned elements of the vacuum pulse shaper can be replaced or sterilized.

The third vacuum filler / slot is designed as an autonomous unit and can be used in existing samples of pneumatically controlled breast pumps for their modernization and improvement of exhaustion characteristics. 1. 2. 3. SOURCE of information: A.S.} 177043, USSR, MM A6I Ml / Ob, 1964, Breastmilk electrosupply for one patient EOM-1, Technical specification (passport). 1986, A.sl 315470, USSR, A6I MI / 06, 1970

Claims (2)

1. A pneumatically controlled vacuum pulse generator for a breast pump, comprising a pneumatic vacuum-atmosphere key located in the housing, made with the possibility of connecting to a vacuum pulse regulator and a milk pump milk collector, characterized in that the pneumatic vacuum-atmosphere key consists of two replaceable elastic nozzles and the mechanism of their clamping, which contains a pneumatic pusher with a pressing element, a spring-loaded bracket having a through groove on the side wall, which is mounted on the rod, nom in the support with the possibility of reciprocating movement in the direction of the pressure member, and a rod mounted on the housing and passing through the through groove in the bracket, while one nozzle is placed on the shelf of the bracket under the pressure member, the other nozzle is on the other shelf of the bracket under the said rod moreover, the nozzles are made with the possibility of connecting at one end to the milk collector, and at the other ends to the vacuum pulse regulator and to the atmosphere, respectively. 2. The shaper according to claim 1, characterized in that it is equipped with a vacuum reservoir connected to a pipe configured to connect a vacuum pulse to the regulator.