RU97242U1 - DEVICE FOR AUTOMATIC IRRIGATION OF PLANTS - Google Patents

Abstract

 1. Device for automatic watering of plants, containing a storage tank with a float, which is a container open at the top, and a siphon configured to move the suction nozzle together with the float in a vertical plane, while the suction nozzle of the siphon is fixed inside the float at the bottom of the float, feeding a container with a filter and a float valve-regulator of the water level in the supply tank, a dropper, the outlet of which is directed to the storage tank, characterized in that inside the storage tank mkosti mounted abutment limiting movement of the float in a vertical plane with the suction pipe of the siphon and is connected to a drip feed tank below the top level of water in the feed flexible tube container, with abutment and dropper configured to regulate their position in the vertical plane. ! 2. The device according to claim 1, characterized in that the dropper is suspended at the end of the lever, the other end of which is pivotally connected to the tank for collecting rainfall, while the control float placed in the tank for collecting rainfall, through an extension cord is connected to the lever between the suspension point of the dropper and the connection point of the lever with the tank for collecting rain.

Description

The utility model relates to agriculture and is intended for automatic watering of plants mainly in home gardens, summer cottages, horticultural and garden plots in the absence of man and without the use of electricity.

The closest technical solution to the problem of filling the storage tank using a supply tank with a stable flow rate, which does not depend on the pressure in the water supply source, has the device presented in the description of patent RU 2217903 C2, A01G 25/02, published 10.12.2003. The device contains a capacity level regulator with a float and a control valve. Below the water level, a drip device is connected to the wall of the tank. By maintaining a constant level in the tank, the flow rate of the drip device will be a constant value, independent of changes in pressure in the water supply source. The disadvantage of this device is that the regulation of the irrigation rate, at the same time, is performed by a water flow divider when draining the siphon of the storage tank by draining the excess volume of water into the additional tank. This method of regulation significantly reduces the efficiency of the use of irrigation water reserves, especially at low irrigation rates, when most of the water can go to drain into an additional tank.

The device for watering plants, presented in the description of patent RU 2081559 C1, A01G 27/00, published on 06/20/1997, allows you to adjust both the amount of irrigation rate and the amount of portions by which this rate will be poured, more rationally. The device contains a supply tank, which is a container with a hole on top. The hole after pouring water is closed by an airtight stopper. A dropper is mounted at the bottom of the tank, covered with an air chamber inside the tank, which has a common bottom with the tank and with an opening at the bottom of the side wall for communication with the tank. The dropper flow rate is stabilized due to the rarefaction that occurs when water expires. The ability to control the flow rate of the dropper is provided by the use of an air valve mounted in the air tube, which communicates the air chamber with the atmosphere. This solves the problem of regulating irrigation, for example, daily allowance. Water from the dropper enters the storage tank with a flexible siphon tube, the upper elbow of which is spring-loaded with a ring. Moving the ring in height, you can change the volume of water that will pour out when the siphon is triggered, thereby regulating the volume of a portion of water and, accordingly, the number of portions that will pour out the irrigation rate.

The disadvantage of this device is that it cannot be connected to a source of constant water supply, because of the need to maintain the tightness of the upper cavity of the supply tank.

Common to both of the devices mentioned above is that in their description there is no indication of the siphon trigger mechanism. From this we can conclude that the passage section of the siphon should be so small that the volume of the last drop would be enough to rapidly increase the water level in the storage tank to the level at which the siphon will start. Otherwise, water will flow through the siphon as it enters the storage tank. The scope of devices with such a small cross-section of the siphon, most likely, as stated in the descriptions of the patents, will be limited to watering mainly single or very limited number of plants.

As a prototype, a device for watering plants, presented in the description of the patent RU 2032318 C1, A01G 27/00, published on 04/10/1995, was selected. The device contains a suction pipe, ending with a floating labyrinth chamber, which has the ability to swing along the height of the storage tank. The filling level of the storage tank is set by a float crane so that when the labyrinth chamber ascends to the upper position, it is within the reach of the control cargo. The load is fixed at the end of the rocker arm inside the storage tank, at the other end of the rocker arm outside the tank, as a counterweight, an evaporative tank with batiste wicks is suspended. At each drain cycle, the evaporation tank is replenished with water. As water evaporates from the evaporation tank, its weight decreases, the control load goes down and floats the labyrinth chamber, thereby triggering the discharge of water from the storage tank. After draining, the device is ready for the next cycle. The device has a tray for collecting and draining rainwater into an evaporation tank, which should provide a delay in irrigation when precipitation occurs.

The disadvantage of this device is its rather complicated setup.

The frequency of irrigation in the device is determined by the length of the suspension arm of the evaporating tank and the rate of evaporation of water from this tank, which in turn depends on the number of evaporating wicks. Given that, in general, the rate of water evaporation depends on specific weather conditions (wind speed, temperature and relative humidity, insolation), obtaining a satisfactory result of the device setup in practice can take a long time. In addition, with this method of setting up the device, if it starts to rain immediately after watering, that is, when the evaporation tank is already full, further operation of the device will occur without taking into account precipitation. When using the device in the open air, that is, not in sheltered ground, most likely it will be necessary to provide for the protection of the rocker arm with an evaporating capacity to prevent false operation of the device due to their possible swaying by the wind. The disadvantage of this device is that watering is carried out with a constant portion of water, although, for example, a cucumber requires maintaining the soil moisture at a constant level, which is ensured by frequent watering in small portions, it is recommended to water the tomato less often, but more plentifully.

The purpose of the proposed utility model is to increase the reliability and expand the capabilities of the device in various operating modes, simplify the regulation of device parameters when it is configured for watering plants with different requirements for irrigation standards or for different phases of their development.

Achieving this goal is ensured by a device for automatic watering of plants containing a storage tank with a float, which is a container open from above, and a siphon configured to move the suction nozzle together with the float in a vertical plane, while the suction nozzle of the siphon is fixed inside the float at the bottom of the float. The movement of the float together with the suction pipe is limited by a stop, the position of which in the vertical plane can be adjusted. The position of the stop will determine the moment of operation of the siphon and, accordingly, the volume of water that will be drained. Water in the storage tank comes from a dropper, which is connected by a flexible tube to the supply tank below the upper water level in the supply tank. The water level in the supply tank is maintained constant by the float valve-regulator, which ensures a stable flow rate of the dropper. To prevent clogging of the dropper and the float-valve, the device is connected to the water supply through a filter. The position of the dropper can be adjusted in the vertical plane between the storage tank and the upper water level in the supply tank, thereby providing the ability to control the irrigation rate per unit time, for example per day. When using the device outdoors to reduce the risk of waterlogging in the event of precipitation, the dropper position can be adjusted depending on the level of precipitation. This is achieved by suspending the dropper on the end of the lever, the other end of which is pivotally connected to the sediment collection tank, while the control float placed in the sediment collection tank is connected through a extension between the suspension point of the dropper and the connection point of the lever with the collection tank .

Thus, the siphon trigger mechanism proposed in the device provides guaranteed drainage of water, eliminating false alarms. Using the movable stop, it is easy to adjust the volume of a portion of the drained water, which allows pouring the irrigation rate in frequent, small portions to maintain soil moisture at a constant level for moisture-loving crops, or to produce a rare but plentiful watering. The float control valve allows you to use any available water supply source, whether it is a tank raised above the ground or a pressure water supply, and at the same time eliminates the effect of changes in water pressure in the source on the stability of the dropper flow. By changing the position of the dropper in the vertical plane, it is possible to smoothly adjust its flow rate, up to turning off the dropper in a position above the upper water level in the storage tank, which makes it convenient to use such regulation also taking into account precipitation. Using a filter to purify water from mechanical impurities will significantly increase the duration of the device without maintenance.

The drawing shows a General view of a device for automatic watering of plants. The device contains a storage tank 1 with a float 2, which is a tank open at the top, a siphon 3 and an emphasis 4, a supply tank 5 with a filter 6, a float valve-regulator 7, a dropper 8, a flexible tube 9 connecting the dropper with a supply tank, a container for sediment collection 10 with a control float 11, an extension cord 13 and a lever 12.

The device operates as follows. From the water supply source, the water, previously purified from mechanical impurities by the filter 6, enters the supply tank 5 through the float valve-regulator 7. Then, through the flexible tube 9, dropper 8, the water is sent to the storage tank 1. The dropper flow rate, respectively, and the irrigation rate, will be determined the height of the water column, defined as the vertical distance between the dropper and the upper water level in the supply tank. For example, with a drip hole of approximately 0.5 mm, a change in the height of the water column by 1 cm results in a change in the flow rate of the dropper by approximately 1.5 liters per day. To determine, for example, the daily irrigation rate that the device will provide for a particular dropper position, it is enough to measure the volume of water flowing out of the dropper in a short period of time and determine the daily volume of water by a simple calculation. If it is not necessary to adjust the flow rate of dropper 8 depending on the level of precipitation, for example, when using the device in closed ground, then the position of the dropper in a vertical plane between the upper water level in the supply tank 5 and the storage tank 1 is fixed in any convenient way, for example, using a bracket (not shown in the drawing), and if the flow rate of the dropper is adjusted taking into account precipitation, then the dropper is suspended at the end of the lever 12, which is pivotally connected with its second end to the collection tank 10. The position of the lever 12 depends on the position of the control float 11, placed in the tank 10 and connected through an extension 13, with the lever 12. In the absence of precipitation, the float 11 is at the bottom of the tank 10 and the height of the dropper 8, to ensure the required flow rate, set by changing the height the connection points of the extension cord 13 and the lever 12. In case of precipitation, the control float 11 pops up, raising the dropper 8 with the lever 12 and, thereby, reducing its consumption until it is completely switched off with a large amount of precipitation. As water evaporates from the sediment collection tank 10, the control float 11 gradually drops, the dropper flow increases while reaching a predetermined flow rate when the control float reaches the bottom of the sediment collection tank. As water enters the storage tank 1, the water level in it rises, the float 2 together with the suction nozzle of the siphon 3 floats until the stop 4 is reached. After reaching the level corresponding to the upper edge of the float 2 in the touch position of the stop 4, the water will begin to fill the float tank 2. When the float tank 2 is filled with water to a state where it will lose buoyancy, the float will fall to the bottom of the storage tank 1 with its own weight, and the siphon 3 will start and the water through the drain pipe will start enter the sprinklers. After lowering the water level in the storage tank 1 to the upper edge of the float 2 lying on the bottom of the supply tank, water will begin to be removed from the float tank, the float 2 will pop up and the device is ready for the next cycle. By changing the position of the stop 4 along the height of the tank 1, you can change the volume of the poured portion of water, while the minimum volume will be equal to the volume of the float tank plus the amount of water needed to close the siphon tube, and the maximum volume will be determined by the volume of the storage tank.

A pre-configured device for automatic watering of plants can operate continuously throughout the growing season of plants when using a constant water supply as a source of water supply. A person’s intervention in the operation of the device may be required in a small number of cases, namely: to clean the dropper from deposits, if not a self-cleaning dropper is used, but irrigation water with a high salt content, to replenish the water supply source, if a reservoir raised above land and, if necessary, the reconfiguration of the irrigation rate in accordance with the need of plants for water, depending on the phase of their development.

Claims (2)

1. Device for automatic watering of plants, containing a storage tank with a float, which is a container open at the top, and a siphon configured to move the suction nozzle together with the float in a vertical plane, while the suction nozzle of the siphon is fixed inside the float at the bottom of the float, feeding a container with a filter and a float valve-regulator of the water level in the supply tank, a dropper, the outlet of which is directed to the storage tank, characterized in that inside the storage tank mkosti mounted abutment limiting movement of the float in a vertical plane with the suction pipe of the siphon and is connected to a drip feed tank below the top level of water in the feed flexible tube container, with abutment and dropper configured to regulate their position in the vertical plane. 2. The device according to claim 1, characterized in that the dropper is suspended at the end of the lever, the other end of which is pivotally connected to the tank for collecting rainfall, while the control float placed in the tank for collecting rainfall, through an extension cord is connected to the lever between the suspension point of the dropper and the connection point of the lever with the tank for collecting rainfall.