RU2004257C1 - Medical syringe - Google Patents

Description

figure 4 - a syringe with a check valve in the form of an elastic membrane mounted in the channel of the needle with the possibility of its overlap, General view.

The syringe consists of a housing 1 with a tip 2, on which a needle 3 with a cannula 4 is mounted and means for changing the pressure 5 inside the housing 1. In the channel of the needle 3, a check valve is installed in front of the cannula 4, the inlet 6 of which is facing the cannula 4 and the outlet 7 to the pointed end of the needle 3.

The non-return valve can be made in the form of a ball 8 jammed in the valve body 9 (see Fig. 1),

The check valve can be made of an elastic material, such as polyethylene, in the form of a flattened nozzle 10 mounted in the channel of the needle 3 (see, Fig. 2).

The non-return valve can be made in the form of a ball 11, spring-loaded in the valve body 9 by a spring 12 (see Fig. 3).

The check valve can be made in the form of an elastic membrane 13 mounted in the channel of the needle 3 with the possibility of its overlap (see figure 4).

All of the above syringes work in a similar way. After taking the medicine by any known method, a cannula 4 with a needle 3 is installed on the tip 2, in which the check valve is placed. After that, an injection is made, while the check valve works to open (the walls of the flattened nozzle 10 are consumed, the ball 8 (see Fig. 1) moves away from the seat of the housing 9 - it is wedged, the ball 11 (see Fig. 3) compresses the spring 12 and moves away from the saddle, the membrane 13 moves away from the inlet 6, passing the drug into the channel of the needle 3. The pressure of the drug inside the body 1 exceeds the internal pressure of the patient who is injected.

Upon completion of the injection, pressure equalization first occurs, leading to the closure of non-return valves, the design of which is shown in Figs. 2 and 3, while the elastic walls of the nozzle 10 are flattened, the spring 12 presses the ball 11 against the inlet 6, blocking the latter.

When the patient's internal pressure exceeds the pressure inside the syringe body, the check valves are closed, the design of which is shown in Fig. 1 and Fig. 4.

In this case, the ball 8 and the membrane 13 are pressed against the inlet 6, blocking it.

As a result, the liquid located in the needle channel cannot enter the internal volume of the syringe body, thereby maintaining stability and making it possible to use it later without sterilizing the body.

The proposed syringe allows highly efficient use in conditions of mass injection, for example, during epidemics, because only a needle with a cannula is subject to replacement, the syringe body does not require sterilization or replacement during an injection to another patient. It is also advisable to use such a syringe when its sterilization is limited, for example in the field. When using syringes of this design, the problems of disposal and material consumption are minimized.

(56) Syringe Record GOST 22967-82

Claims (5)

1. A MEDICAL SYRINGE, comprising a case with a tip, on which a needle with a cannula is mounted, and means for changing the pressure in the case, characterized in that that a check valve was introduced into the mist before the cannula, the inlet of the body of which is facing the cannula, and the outlet is of the pointed end of the needle. 2. The syringe according to claim 1, characterized in that. that the check valve is made in the form of a ball mounted with the possibility of jamming in the valve body. 3. A syringe according to claim 1, characterized in that the check valve is made of an elastic material in the form of a flattened nozzle. 4. The syringe according to claim 1, characterized in that the check valve is made in the form of a ball spring-loaded in the valve body. 5. The syringe according to claim 1, characterized in that the check valve is made in the form of an elastic membrane with the ability to block the needle channel. t 5 i i. f i i ii i i i I I & ,. L I 5 2 It 6 10 7 Ј.,. 2. Li 6 8 9 At 5 2 b 6 D C 9 l s / / / / / - f and / / Y / s / i FIG. 3. i / y 6 F „l.