SU1631040A1 - Metering device for liquids - Google Patents

Abstract

The invention relates to packaging equipment and can be used, for example, for the dosing of biological preparations. The aim of the invention is to increase productivity. In the initial position, the piston 6 is in contact with the upper end of the upper lid of the cylindrical vessel 1. When the vessel 1 moves under the action of the rod 4 up above the end of the piston 6, a cavity is formed that is filled with liquid through the nozzle 2 through slot 7. vessel lid 1. Then the piston 6 will turn 180 & and its groove 7 is located at the nozzle 3, and the groove 8 of the nozzle 2. Next, the rod 4 with the vessel 1 begins to move downwards, and under the lower end of the piston 6 a cavity is formed, which through the nozzle 2 and the groove 8 is filled with liquid. At the same time, the liquid dispensed, located in the cavity above the upper end of the piston 6, is squeezed out through the groove 7 of the piston 5 into the fitting 3. 3 Il.

Description

The invention relates to packaging equipment and may be ncnonbSOBaHOj for example, for dosing of biological preparations.

The aim of the invention is to increase productivity.

In Fig. 1, the proposed device, a general view; in FIG. 2 is a section AA in FIG. 1; in FIG. 3 - dispenser with a lower piston.

The device consists of a cylindrical vessel 1 with inlet and outlet fittings 2 and 3, respectively, located diametrically opposite in the middle part on its lateral surface, and mounted on a rod 4 with the possibility of reciprocating movement mounted in the vessel 1 with the possibility of reciprocating movement from the rod 5 of the piston 6 with the grooves 7 and 8 formed on it diametrically opposite, the latter being formed on the side surface, are equal in length and open from opposite ends of the piston 6, a cylindrical tide 9 is made at the free end of the latter, and the ratio of the length of the cylindrical vessel 1 to the length of the piston 6 is 1.3: 1, the ratio of the length of the piston 6 to the length of the grooves 7 and 8 is 1.4: 1.

The dispenser for liquids works as follows ’.

When rod 5 is completely extended from cylinder 1, the piston 6 contacts the end cap of the cylinder 1, the groove 7 of the piston 6 against the inlet 2 and the groove 8 against the outlet 3 by the rod 4, the cylindrical vessel 1 begins to move upward with the rod 5 stationary and piston 6. As a result of the ratio of the length of the cylindrical vessel 1 to the length of the piston 6 and the ratio of the length of the piston 6 to the length of each of the grooves (7 and 8) 1.3: 1 - 1.4: 1 the piston 6 does not overlap the nozzle 2 and 3. Therefore, a cavity is formed over the upper end face of the piston 6, which the first one is filled with liquid from the container with the dosed liquid through the inlet 2 along the groove 7. The filling of the cavity of the cylindrical vessel 1 under the upper end of the piston 6 ends when the cylindrical tide 9 at the end of the piston 6 is in contact with the bottom cover of the cylindrical vessel 1,

Then, a pulse rotation of 180 ° of the rod 5 and the piston 6 connected to it is performed. In this case, the groove 7 of the piston 6 is located at the output nozzle 3, and the groove 8 is at the input nozzle 2. Further, making a reciprocating movement, the rod with a cylindrical vessel 1 begins to move downward with the stationary rod 5 and piston 6.

Below the end and tide 9, a cavity is formed in the cylindrical vessel 1, which is filled through the inlet fitting 2 and the groove 8 with the dosed liquid. At the same time, the dosed liquid located in the cavity of the cylindrical vessel 1 above the upper end face of the piston 6 is squeezed out along the groove 7 of the piston 6 and enters the dosed container through the outlet nozzle 3. The movement of the rod 4 with the cylindrical vessel 1 is carried out until the dosing liquid is completely removed and the upper end of the piston 6 is in contact with the upper cover of the cylindrical vessel 1. In this case, the cavity under the lower end of the piston 6 is filled with the dosed liquid. Then there is a pulse rotation of the rod 5 and the piston 6 through 180 °. As a result, the groove 7 of the piston 6 is located against the inlet fitting 3. The cavity under the lower end of the piston 6, filled with a dosed liquid, is in communication with the outlet fitting 3.

The rod 4 with the cylindrical vessel 1 begins to move upward relative to the stationary piston 6. The dosed liquid through the inlet 2 and the groove 7 of the piston 6 enters the forming cavity in the cylindrical vessel under the upper end face of the piston 6. At the same time, from the cavity of the cylindrical vessel 1 located below the lower end the piston 6, the dosed liquid through the groove 8 of the piston 6 and the outlet nozzle 3 goes into the dosed container. Next, the filling cycle is repeated.

As a result of the equality of the volumes of the part of the rod 5 of the piston 6 located in the cylindrical vessel 1 and the cylindrical tide 9 at the lower end of the piston 6, the doses of liquid in the upper and lower cavities of the cylindrical vessel 1 are equal. Thus, with each stroke of the cylindrical vessel 1, a dose of liquid is filled.

The design of the dispenser and the ratio of the sizes of its elements are determined theoretically and experimentally. When the ratio of the length of the cylindrical vessel 1 to the length of the piston 6 and the length of the piston 6 to the length of the grooves 7 and 8 is less than 1.3: 1, the piston occupies most of the cylindrical vessel and the dispenser is not used efficiently.

When the ratio of the length of the cylindrical vessel 1 to the length of the piston 6 and the length of the piston 6 to the length of the grooves 7 and 8 is more than 1.4: 1, the reliability of the seal with the piston decreases, therefore, fluid leakage can occur bypassing the piston.

Claims (1)

Claim A liquid dispenser comprising a cylindrical vessel mounted on a rod with the possibility of reciprocating movement with inlet and outlet 5 fittings located diametrically opposite in the middle part on its side surface mounted in a vessel on the rod with the possibility of reciprocating and rotary 10 joints of the piston with a groove open from the side of its end for communication with the body fittings, characterized in that, in order to increase productivity, the piston is diametrically opposite the main groove is formed an additional groove, and a cylindrical tide is made on the free end of the piston, while the grooves are formed on the side surface, are equal in length and open from opposite ends of the piston, the ratio of the length of the cylindrical vessel to the length of the piston is 1.3: 1.0, and the ratio of piston length to groove length is 1.4: 1.0. Fig.Z