WO2023211310A1 - Manually driven spray pump - Google Patents

Abstract

The invention relates to the field of agriculture. A spray pump comprises a cylinder having mounted at one end thereof a check valve, configured in the form of a ball, and a suction nozzle and having mounted at the other end a hollow spraying rod which is mounted inside a stepped piston with a delivery valve. The delivery valve is configured in the form of a ball and is mounted in an axial through-cavity of the piston with a restrictor for restricting movement in the piston region. The restrictor for restricting movement of the ball is formed by a seat of an outlet port of the piston and by bosses on the walls. The ball of the check valve is mounted and restricted in movement between a seat of an outlet port of the cylinder and the end of the piston. Mounted above the cylinder is a reservoir, an outlet port of which coincides with an inlet port of the cylinder. A nozzle for attaching a liquid delivery hose to the pump is arranged on the side in the lower part of the reservoir. The cavity of the rod has a uniform diameter across its entire length up to the reservoir. The invention obviates the need to constantly pump liquid to a spraying nozzle and is less tiring for a user to operate.

Description

MANUAL SPRAYER PUMP

DESCRIPTION

The solution relates to the field of agriculture, namely liquid sprayers, and can be used for treating plants and whitewashing premises.

A device for supplying liquid under pressure is known, including a double-acting piston pump made in the form of concentrically placed working and internal pistons (see SU1369822, B 05 B 9/04).

The disadvantages of the analogue are the increase in transverse dimensions due to the concentric arrangement of the pistons, and therefore the effort to move them, which makes the use of a technical solution for manually driven devices impractical.

A manually driven sprayer pump is known, containing a cylinder, at one end of which a check valve and a suction fitting are mounted, and at the other, a hollow spray rod mounted inside a stepped piston with a discharge valve and side holes of a smaller diameter, while the discharge valve is made in in the form of a rubber ring installed with a gap along the outer diameter of the piston with the possibility of movement in the axial direction on the piston between the shoulders, a check valve - in the form of a ball in the fitting hole (see SU1650053).

The disadvantage of the analogue is that it is low-tech due to the different design of the valves, as well as additional wear on the piston seal due to its mobility - breaking on the shoulders.

The closest analogue is the solution according to patent RU2130257, published: 05.20.1999, which ensures that the seal is immobile relative to the piston, as well as the discharge valve is made in the form of a ball. The prototype solution reflects a manually driven spray pump containing a cylinder, at one end of which a check valve and a suction fitting are mounted, and at the other end a hollow spray rod mounted inside a stepped piston with a discharge valve and side holes on smaller diameter, characterized in that the discharge valve is made in the form of a ball installed in the through axial cavity of the piston, and in the area of the side holes of the piston, between the inner wall of the piston and the outer surface of the rod, a gap is provided, and the end of this rod on the side of the ball is flattened to clearance , smaller than the diameter of the ball.

The technical problem of the prototype is that it contains many cavities for the flow of liquid, and therefore the effort to move them. In addition, one cylinder movement is equal to one nozzle injection, which leads to rapid user fatigue and makes it impractical to use a technical solution for manually driven devices.

The task is to eliminate the specified technical problems of the prototype.

The technical result is to eliminate the need for constant injection of liquid into the nozzle and reduce user fatigue when working with the pump.

The specified technical result is achieved due to the fact that a manually driven sprayer pump is claimed, containing a cylinder, at one end of which a check valve in the form of a ball and a suction fitting are mounted, and at the other end - a hollow spray rod mounted inside a stepped piston with a discharge valve, wherein the discharge valve is made in the form of a ball installed in the through axial cavity of the piston with a movement limiter in the piston area, characterized in that the ball movement limiter is formed by the piston outlet seat and bulges on the walls, the check valve ball is installed and limited by movement between the cylinder outlet seat and the end of the piston, a capacitive reservoir is installed above the cylinder, the outlet of which is combined with the inlet of the cylinder, and the fitting for securing the liquid supply hose to the nozzle is located on the side in the lower part of the capacitive reservoir, and the cavity of the rod is made along the entire length to the capacitive reservoir with the same diameter.

Brief description of drawings Figure 1 shows a schematic design of a utility model (side sectional view) showing the upward movement of the piston to pump liquid into the pump cylinder area.

Figure 2 shows a schematic design of a utility model (side sectional view) showing the downward movement of the piston to pump liquid into a capacitive tank.

In the drawings: 1 - handle, 2 - seal for the connection of the handle and the capacitive reservoir, 3 - capacitive reservoir (hydraulic accumulator), 4 - seal for the connection of the piston and the capacitive reservoir, 5 - piston, 6 - adapter, 7 - adapter seal, 8 - outlet rod, 9 - discharge valve ball, 10 - fitting, 11 - fitting seal, 12 - sleeve, 13 - check valve ball, 14 - hose, 15 - nozzle, 16 - capacitive reservoir (hydraulic accumulator) fitting, 17 - convexity, 18 - pump cylinder.

The claimed manually driven spray pump consists of a cylinder, at one end of which a check valve in the form of a ball and a suction fitting are mounted, and at the other end there is a hollow spray rod mounted inside a stepped piston with a discharge valve.

The discharge valve is made in the form of a ball installed in the through axial cavity of the piston with a movement limiter in the piston area.

What is new is that the ball movement limiter is formed by the seat of the piston outlet and bulges on the walls, the check valve ball is installed and limited by movement between the seat of the cylinder outlet and the end of the piston, a capacitive reservoir (hydraulic accumulator) is installed above the cylinder, the outlet of which is combined with the inlet cylinder, and the fitting for securing the liquid supply hose to the nozzle is located on the side in the lower part of the capacitive reservoir, and the cavity of the rod is made along the entire length to the capacitive reservoir with the same diameter.

The utility model can be designed as follows (see Figure 1).

The sprayer pump contains a cylinder 18, at one end of which a fitting 10 is mounted.

The check valve is made in the form of a ball 13. A stepped piston 5 with a through stepped outlet hole 8 is installed in the cylinder 18. In the outlet In the hole 8 of the piston, the ball 9 of the injection valve is placed freely and a hollow capacitive reservoir (hydraulic accumulator) 3 is fixed with an outlet fitting 16, which is located on the side in the lower part of the reservoir 3 and serves to supply liquid through the hose 14 and then through the nozzle 15.

This design of the end part of the piston 5 does not have, as in the prototype, a solid convexity with gaps smaller than the diameter of the ball. In the claimed solution, the ball 9 in its movement is limited on one side by the seat of the outlet hole 8, and on the other by convexities 17 in the inner side walls of the piston 5.

Thus, the compression force of the piston is reduced, there is no need to constantly pump liquid into the nozzle, and therefore the user’s fatigue when working with the pump will decrease.

The pump works as follows.

Position as in Fig. 1 - when the piston 5 moves upward relative to the cylinder 18, when the end of the cylinder is immersed by the fitting 10 in a certain container of water (not shown), liquid is sucked in. At this time, ball 9 closes the hole in piston 5 at the seat.

When the piston moves back down (see Fig. 2), the liquid through hole 8 enters the capacitive reservoir (hydraulic accumulator) 3 already freely, since the ball 13 of the check valve at this time locks the fitting, and at the same time, the ball 9, pressing against the bulges 17, does not restrict the movement of water flow into the capacitive reservoir (hydraulic accumulator) 3.

In this way, liquid is pumped into the capacitive reservoir 3 and pressure is created in it.

After creating pressure in the capacitive reservoir (hydraulic accumulator) 3, the liquid is squeezed out through fitting 16 and flows through hose 14 to spray nozzle 15.

One person operates the pump.

The capacitive reservoir can be made in the form of, for example, a plastic bottle screwed onto the end of the rod 5 through the seal 4.

It is also possible to make a handle 1 for ease of carrying the pump, which can be secured through a threaded connection in the upper part of the capacitive reservoir 3 through the seal 2, which allows it to be screwed in.

Claims

FORMULA

A manually driven spray pump containing a cylinder, at one end of which a check valve in the form of a ball and a suction fitting are mounted, and at the other end - a hollow spray rod mounted inside a stepped piston with a discharge valve, wherein the discharge valve is made in the form of a ball installed in a through axial cavity of the piston with a movement limiter in the piston area, characterized in that the ball movement limiter is formed by the piston outlet seat and bulges on the walls, the check valve ball is installed and limited by movement between the cylinder outlet seat and the end of the piston, a capacitive reservoir is installed above the cylinder ( hydraulic accumulator), the outlet of which is combined with the inlet of the cylinder, and the fitting for securing the liquid supply hose to the nozzle is located on the side in the lower part of the capacitive reservoir, and the rod cavity is made along the entire length to the capacitive reservoir with the same diameter.

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