RU2095760C1 - Liquid metering pump - Google Patents

Abstract

FIELD: water supply. SUBSTANCE: liquid metering pump has body, siphon pipe, additional vessel mounted in body for turning and interaction with rest and fitted with float manufactured in the form of vessel turned upside down and located on part of additional vessel opposite to rest. Top of siphon pipe is positioned above lower edge of float. EFFECT: simplified design, improved functional reliability. 2 dwg

Description

 The invention relates to water supply and can be used in various industries and agriculture related to the use of metering devices for liquids.

Known liquid dispenser in the drain device, made in the form of a housing and placed in it "G" -shaped float with a block containing a valve connected by a flexible thread to the block [1]
The main disadvantage of this dispenser is the possibility of fluid leakage through the valve due to inaccuracy in the manufacture of the surfaces of the valve joint, as well as due to the presence of impurities or deposits of substances insoluble in the liquid.

Known fluid dispenser as.with. N 1201437 C. E 03 D 1/00, consisting of a housing, a siphon tube and a hermetically welded to the partition wall, provided with a central air outlet and a strictly defined neck for supplying liquid to the dispenser [2]
The main disadvantage of this dispenser is the limited technological capabilities, due to the fact that the dispenser can only work with a limited to a certain amount of minimum fluid flow into the dispenser, excluding, for example, any drip fluid flow into the dispenser.

 The objective of the invention is the expansion of technological capabilities.

 This problem is solved in that the dispenser comprising a housing with an additional container and a siphon tube located therein is provided with a stop fixed in the housing, and the additional tank is placed on the axis with the possibility of rotation and interaction with the stop and is equipped with a float made in the form of an inverted tank, and the axis located under the center of mass of the additional capacity, and the top of the siphon tube above the lower edge of the float.

 In FIG. 1 shows the proposed design of the liquid dispenser at the time of unstable equilibrium of the additional capacity (the beginning of the “somersault”), in FIG. 2 the same dispenser at the moment of operation after the “somersault” of the additional capacity (liquid outflow through the siphon tube).

 The liquid dispenser consists of a housing 1, an additional container 2, mounted for rotation on the axis 3, a siphon tube 4. From the bottom (or side) to the additional container 2, a hollow float 5 is installed, made in the form of an inverted container. An emphasis 6 is fixed on the housing 1, which holds the additional container 2 in a horizontal position while filling it with liquid. The float 5 is located on the opposite abutment 6 of the part of the additional container 2. The siphon tube 4 is installed so that the top of the siphon tube is located above the lower edge of the float (to avoid the outflow of liquid through the siphon tube until the additional tank 2 is tipped over). The fluid is supplied to the dispenser through the pipe 7, which is installed above the zone of location of the internal circuit of the additional tank.

 The dispenser works as follows. In the initial position, due to the imbalance in the mass of the float, the additional tank 2 experiences a torque that presses it against the stop 6, keeping it in a horizontal position.

 The liquid coming from the pipe 7 at any intensity, incl. in the form of drops, first fills the additional container 2, and then flows over the edges into the dispenser housing. When the liquid level in the housing 1 rises until it touches the float 5 and the subsequent intake of liquid, the air enclosed in the float 5 prevents the penetration of the liquid into the float, and it begins to experience buoyancy force according to the Archimedes law, equal to the weight of the displaced flooded part of the float. As a result, the additional capacity 2 begins to act on the torque, which tears it from the stop 6.

 Upon reaching the liquid level I-I additional capacity 2 passes the zone of unstable equilibrium and turns over. Liquid is poured instantly from this tank, and a new level of liquid II-II is installed in housing 1. In this case, the curved part of the siphon tube 4 is flooded, and through the siphon tube, liquid drains from the dispenser housing. When turning the additional tank 2, part of the liquid enters the cavity of the float 5, but no longer affects the rotation of the tank 2.

 In the process of discharge, the additional container 2 is turned in the opposite direction and before the touch of the float 5 with the liquid returns to its original position until it touches the stop 6. In this case, the liquid from the float 5 is completely drained into the dispenser housing 1. And so the process is repeated periodically in a systematic mode, ensuring that the liquid is drained in a dosed volume at any liquid flow into the dispenser, including drip.

 The proposed liquid dispenser is very simple to manufacture and reliable in operation. Provides the ability to create dispensers of any capacity. It can be used in any industry and agriculture, including for automatic watering of plants in greenhouses or in garden beds without the participation of an employee, using the available fluids or water supply connected to the dispenser via a valve that can be adjusted to the required fluid flow rate during the day or week (including with a drip of liquid into the dispenser).

Claims (1)

 A liquid dispenser comprising a housing with an additional container and a siphon tube located in it, characterized in that it is provided with a stop fixed in the housing, and an additional tank is placed on the axis with the possibility of rotation and interaction with the stop and is equipped with a float made in the form of an inverted tank, located on the opposite emphasis of the part of the additional capacity, the axis being located under the center of mass of the additional capacity, and the top of the siphon tube above the lower edge of the float.

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