SU983309A1 - Hydralically driven diaphragm pump unit - Google Patents

Description

the flow of the drive medium relative to the low pressure point, with hydraulic resistance between the high and low pressure points.

Moreover, between the points of high and low pressure in the main pipeline, a cross-section can be installed.

Figure 1 shows the constructive scheme of the pump unit; Fig.2 pumping unit on an enlarged scale; on fig.Z - diagram of the pump unit in one extreme position of the diaphragm; in fig. 4 - the same, in the other extreme position of the diaphragm. In the housing 1 of the pump unit there are two drive chambers 2, separated by a diaphragm 3, equipped with a rigid center 4 of the drive. The hard center 4 is made hollow and two pump chambers 5 are formed therein. The latter are separated by a central portion of the common diaphragm for the drive and pump chambers 2 and 5. The central part of this diaphragm 3, which separates the pumping chambers 5, is peripherally connected to the rigid center 4 of the drive. The diaphragm 3 is provided with a rigid center b of the pump located in the hollow center 4, which is connected to the housing 1 by the rack 7 passing through the holes 8 made in the hard center 4. The pumping chambers 5 communicate with the block 9 through the channels 10 , made in rack 7. Valve block 9 is also connected to the tank 11 for the input component H.anpiiMep fertilizer, and to the main pipeline 12 of the driving medium, which is served, for example, by water. The main pipeline 12 of the driving medium serves as the supply hydraulic system of the drive and connected Erez controllable valve 13 to the points 14 and 15 respectively of high and low pressure .. The point 14 is located on the high pressure conduit 12vyshe downstream drive fluid flow relative to the low point 15 Vdavleni. Between points 14 and 15, a choke (not shown) can be installed. The valve block 9 is connected to the pipeline 12 at the low pressure point -15. The controllable valve 13 is driven to move the spring 16, the lever 17 and the connecting rods 18 are connected to the rigid center 4 of the actuator. From: versts 8 in the hard center 4 of the drive are equipped with sealing nodes 19. When the flow medium flows through the main pipeline 12 between high and low pressure points 14 and 15, a pressure differential occurs due to length losses or local losses at the throttle: Distributor 1 reports one from drive chambers 2

Claims (6)

for example, the upper one, with a high pressure point 14, and another chamber 2, for example, the lower one (Fig. 1 / - with a low pressure point 15). At the same time, a pressure differential occurs on the diaphragm 3, causing it to move with the rigid center 4 of the drive (in In this case, down in the drawing, since the rigid center b of the pump remains stationary due to communication with housing 1, then when the hard center 4 slides along the rack 7, the volume of pump amers 5 changes (Fig. 3 and 4 h). input component comes from the tank 1 through the block of 9 channels to the iod Well, pumping chamber 5, and from another pumping chamber 5 is forced out through block 9 of the channels into the main pipeline 2, where it is mixed with the drive medium and the resulting solution is carried to the consumer. At the end of each turn, the center 4 through the links 18, lever 17 and spring 16 acts on the distributor 13 by switching it to the opposite position for reversing the diaphragm 3. By placing the pumping chambers 5 inside the hollow rigid center 4 of the drive, the compactness of the pump unit and its reliability are increased due to the fact that leakage is prevented. o component, which can be toxic, to the atmosphere. Claims 1. Hydraulic diaphragm pumping unit comprising a housing in which two drive chambers are made, separated by a diaphragm equipped with a rigid drive center, and two pumping chambers also separated by a diaphragm connected with a rigid drive center the center of the pump, the valve block connected to the pumping chambers, and the control valve connected to the drive chambers and the high and low pressure points of the supply hydraulic system, so that, in order to increase compactness and reliability, the hard drive center is made full, the diaphragm separating the pumping chambers is connected with it around the periphery and is located together with the pump chambers in its internal cavity, and the hard center of the pump is connected to the housing passing through a hole in the hard center of the drive, the pumping chambers communicating with the valve block through channels made in the rack. 2. A pop-1 unit, characterized in that the diaphragms separating the driving and pumping chambers are formed by sections of a single diaphragm of the pumping unit. 3. The unit according to claim 1 and 2, about tl and h ay u and with the fact that the holes in the hard drive center for the passage of the rack are equipped with sealing units. 4. The unit PP. 1-3, characterized in that the controlled valve is kinematically coupled to a rigid drive center. 5. The unit according to claims 1-4, characterized in that the main hydraulic system is the main the drive medium piping, and the high pressure point is located on the pipeline upstream of the drive medium flow relative to the low pressure point, with hydraulic resistance located between the high and low pressure points. 6. An assembly according to claim 5, characterized in that a throttle is installed between the high and low pressure points in the main pipeline. Sources of information, taken into account in the examination five 1. Patent of Germany No. 1138637, cl. 59a 35, 1963.  m I / l