SU277439A1 - AUTOMATED SECTIONAL INSTALLATION FOR PLANT MINERAL NUTRITION - Google Patents

Description

The invention relates to aztomatics of advanced seponion plants for multi-nutritional plants and can be used in heat supply facilities for groundless plant growth.

Known automatic installations for mineral threading of plants include racks with a substrate for plants, a reservoir with a practical solution, a pump, piping for feeding the nutrient solution to the racks and transferring it to a reservoir, an electrical control system and a distribution device consisting of a housing with an inlet, outlet and central non-repus openings of a drive disk with inlet and bypass channels installed in this housing. Odiako known installations do not provide a quick drain of the nutrient solution from the racks, which is due to the fact that the drain of the solution is carried out by gravity. In addition, in known installations, the solution runoff from each rack is carried out into the tank and there is no possibility of feeding the solution into the next rack directly from the previous one, which leads to an increase in the required capacity of the tank for the nutrient solution.

connected to an alternate of the upper openings of the housing of the distributor device, and the neutral bypass opening of this housing is connected to the supply pipe of the feed solution from the reservoir of the help of the interconnecting valve through the distributor and pump of each subsequent stellar valve, first of all, with a separate valve, first through the distributor and the pump of each subsequent stellar valve, first of all, with a separate valve, first through the distributor and the pump of each subsequent stellar valve, first with the previous stack, first through the distributor valve and the pump of each subsequent stellal device, first with the previous stack, first through the distributor valve and the pump of each subsequent stellal valve, first with the previous rack, first through the distributor valve and the pump of each subsequent stellal valve, first with the previous stack, first through the distributor valve and the pump of each subsequent stellal valve, first with the previous stack, first through the distributor valve and the pump of each successive stellar valve and first of all the subsequent stellal valve with the distributor through the distributor and the pump of each subsequent stellal valve and first of all

with a reservoir for an imitative solution.

FIG. 1 shows the scheme of the proposed installation (the moment of feeding the nutrient solution in the nerve rack); in fig. 2 - the same (time of runoff I1ggatenogo solution nz first rack and feed this solution to the next rack); pa fpg. 3 - section along L-A on phpg. one; in fig. 4 - view of the arrow B; in fig. 5 - reversing valve in different nozholenp x (varpapt vypolpenn); in fig. 6 -

electrical installation diagram.

The proposed sectional installation includes racks 1, 2, 3, p 4 with a substrate for plants, tank 5 with a nutrient solution, Pasos 6 with a lead from an electric motor

7, the control panel 8, the switchgear consisting of the case 9 with the inlet 10, the outlet 11 and the non-repetitive 12 opening of the drive plate 13 installed in this case with the inlet disk 13 with the inlet 14

on the shaft 16 with the drive 17, as well as the pipeline 18 for feeding the nutrient solution to the stellum and the pipeline 19 for draining this solution into the tank 5. The pipeline 19 is connected to one of the outlets of the housing 9, the rest of the outlet ports of which are connected by pipelines 20, 21, 22 and 23, respectively, with shelves I, 2, 3, and 4, equipping their heaters with valves 24, 25, 26, and 27 levels of solution.

The central bypass hole 12 of the housing 9 is connected by a pipe pipe 28 and a flip clan 29 to a pipe 18. The valve 29 is connected by a pipe 30 to a pump 6, which, in turn, is connected by a pipe 31 to a two-way valve 32 to the outer hole 10 of the housing 9. To the crane 32, a pipeline 55 is installed to drain the nutrient solution into the sewage system if it is poisoned in the racks. The operating member of the valve 29 can be made in the form of a hinged curtain 34, which, under pressure or from below or above, is installed in iololcium I or II, thereby connecting each subsequent rack (for example 2) first through the distribution device and the pumping station. previous rack /, and then with the tank 5.

FIG. 5 shows another embodiment of a valve 29, according to which it consists of corus 55 and a porsche 36, which can freely move inside the corns 55 with pressure of the nutrient solution, together with pipeline 30 going to the pump, with pipelines 28 or 18.

A pressure sensor 37 is mounted on the housing 9 of the distributor. The device is electrically connected via the control panel 8 to the actuator 17 and the electric motor 7. The pipeline 19 includes a pressure sensor 38, which ensures that the control system is turned off after the last rack is drained into the reservoir 5.

For the preparation of the nutrient solution, the installation comprises a block 59 for the preparation of concentrated nutrients and a unit 40 for dispensing water and concentrated nutrients into the tank 5. In tank 5, a regulator 41 of the nitrating solution, a solution heater 42, a thermal alarm 43 for controlling the temperature of a rastor and a temperature regulator 44 for adjusting the temperature of the nutrient solution are installed. The installation is equipped with an electric automatic control system.

To provide successive nodachp of the nutrient solution to the racks, the bypass drip 15 of the drive disk 13 of the distribution device is designed in such a way that when the inlet channel 14 of this disk is combined with one of the outlet holes 11 of the housing 9, it only connects

with the previous in the direction of rotation of the disk 13 (arrow B in Fig. 3), the extract hole of the cornus of the distribution device. The location of the channel 15 relative to the inlet Kang. 14 on the fng. 3 is shown by a dotted line.

The installation works as follows. On the remote control 8 prp help command apiarata KA (clockwork)

or the start button II switches on the automatics relay / M, the contacts of which close the day of the PH relay of the pump, which closes the pump 6 circuit with its contacts. In this case, the switchboard 13 is in position of the PPM corresponding to the supply of the mounting solution in the rack. In this case, the drive 17 is disabled, since the MVD microswitch corresponding to the specified disk position / 5 is open.

Turning on the pump 6 causes the injection of a thin solution in the tank 5 to the pipeline 18 through the valve 29, the working body of which is in position I, but to the pipelines 30 and 31, through the distributor

The device and its pipeline 20 in rack 1. After the rack’s irregularity / ion-clan clan 24 blocks further 1st access of the solution to this rack, the pressure in the system increases, the pressure sensor 57 activates and contacts the P1 relay circuit, which causes the drive 17 to turn on and off relay pump PH, and, consequently, to stop the pump 6. Natrivod 17 begins to turn back the disk 13 along arrow B and together

With it, cam K before unlocking the MD2 switch. This position corresponds to the feeding of the dilution solution into rack 2. However, this vnusnuy channel 14 of the disk 13 coexists with the outlet 11 of the housing 9,

to which the pipeline 21 of the rack 2 is connected, and the pipeline 20 of the rack 1 through the bypass channel 15 of the dns 13, the central non-drain hole 12 of the housing 9, the pipes 28, 30 and 5 / (claian 29 in this case takes position II) pump 6 communicates with the inlet hole 10 of the cornea 9 and, consequently, with the pipeline 21 nodachp ntatelnogo solution in rack 2. Opening the microswitch MB2 causes shutdown

relay P2 and P1 and the drive 17. Disconnected switch P1 B1c1 causes the PH switch to be switched on by means of a normally closed contact PL The pump 6 is turned on, and the nutrient solution is pumped from rack 1 to rack 2.

So far a part of the solution is discharged by plants in the rack 1, the float valve 25 doesn’t work and the working body 34 of the non-valve valve 29 regains position I under the influence of the solution coming

by gravity from the reservoir 5, which is located above the changeover valve 29. When the rack 2 is filled, the float valve 25 is activated, the system is depressed and the sensor 57 switches off the pump 6 and the racks are turned on in the same way.

After filling the nalid racking for the activation of the sensor 37, the pump 6 is turned off and the disk 13 is turned by the actuator 17 to align the inlet channel / -4 with the pipeline 19 to drain the solution into the tank. When pressure is detected in the pipeline 19, the manometric sensor is triggered and switches the contact from position G to position D. This activates the relay, and is prepared to turn on the relay P4. After the solution has run out from the bottom of the rack 4, the pressure in the pipeline 19 hits to zero, the sensor 38 does not reconnect the contact G and the relay P4 is activated. At the same time, the MV5 microswitch contact and P4 contact closes the P2 relay day and de-energizes the entire system with the exception of the P2 relay, which ensures the operation of the actuator 17 until the cam / does not open previously closed the MV1 microswitch. 17. The Sun system appears in the initial state of operation and is again ready for operation in the cycle described above.

To stop the system at any time, button C is provided.

Subject matter

An automated sectional apparatus for mnneralnogo iitani plants comprising Stellan and a substrate for plants, tank with the nutrient solution, pumps, pipelines iodachn nntatelnogo solution for shelves and draining it into the tank elektr11cheskuyu snstemu control n raspredelntelnoe device consisting nz housing with an inlet, an outlet In the central non-recess openings of the drive disk installed in this housing with a vnuschny n non-opening channels, characterized in that, in order to reduce the run-off time of the drive nogo solution of racks and reduce the necessary e; the reservoir, the pipeline for draining the nutrient solution into the tank is connected to one of the expansion openings of the distribution device housing, and the central bypass opening of the distribution device is connected to the feed solution supply pipeline from the transfer valve through the distribution valve n the pump of each next the rack first with the usual rack, and then with the reservoir for the nutrient solution.

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eight

FIG. 6