SU1514299A1 - Fish pump - Google Patents

Description

The invention relates to devices intended for the diversion of young fish from fish protection devices of water intake structures, and can also be used to transfer live or commercial fish in fish farms or fish processing plants. The purpose of the invention is to simplify the design of the fish pump and to increase the pressure and flow rate of fish water pulp during its operation. To do this, the movable nozzle 7 and the confuser 4 form a nozzle, passing through which at high speed, the working water in the mixing chamber 3 transfers energy

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pumped pulp, determining

the magnitude of the pressure and flow of the latter.

These values are determined by the size of the gap of the nozzle 14, which can be changed using ₅ devices for adjusting the mode of operation, in which the rotation of the shaft

12 through gear II and gear wheel 10 is transferred to the movable pipe 7 14 passes into its translational motion along the axis of the fish pump axis due to its threaded connection 9 with a fixed pipe 6. 2 IDs.

The invention relates to fish pumps, namely, devices designed for the diversion of young fish from fish protection devices of water intake structures, and can be used to transfer live or commercial fish, for example, in fish farms or in the plant ?. 20

on fish processing.

The purpose of the invention is to simplify the design of the fish pump and increase the pressure and flow of fish pulp - water during its operation. 25

Figure 1 shows the fish pump, a longitudinal section; figure 2 - pump unit, a general view.

Rybopump (Fig. 1 3 includes a housing 1 with a branch pipe 2. In the upper part of the housing 1 there is a mixing chamber 1, 3 adjacent to the confuser 4 and a diffuser 5. In the lower part of the housing 1 there is a suction channel consisting of two telescopes 35 ki connected by pipe 6 and 7. Pipe 6 is rigidly connected to the bottom 8, and ¹ pipe 7 is made movable and ι by means of external thread 9 is connected to the stationary pipe b, a gear wheel сажθ is mounted on the backbone 7 and meshes with the gear wheel 11, fixed to hall 12, which passes through a hole in the roof ke

13. Between the pipe 7 and the confuser 45 4 there is a nozzle 14. If necessary, the shaft 12 is supplied with a rod 15.

The fish pump 16 (FIG. 2) can be used in various installations, in particular, be part of a pump installation for irrigating fields, including the main pump 17, a sorozader - a living grid (not shown), a conical screen filter 18, which ensures the retention of juvenile fish and small litter, a device for cleaning the filter from contamination (not shown), a channel 19 for draining 18 of young fish and washed off litter from the filter cavity, a pressure pipeline 22, and a pipeline 20 for supplying working water to a fish pump, a valve 21,

Pump installation works as follows.

When the main pump 17 is operating, the water leaving it moves in two directions: through pipeline 22 to the irrigation network of the fields and through pipe 20 to the fish pump 16. Filter 18 retains small litter and fish and thus prevents fish from entering the pump 17 to its injury. The fish is removed from the cavity of the filter 18 into the reservoir through the pipeline 19, the flow in which is maintained by the fish pump 16. The filter is cleaned of the litter adhering to its surface continuously due to the work of the cleaning device (not shown). The litter removed from the filter, also discharged into the reservoir through the pipeline 19.

The working water entering the cavity of the body 1 of the fish pump flows out of the nozzle 14 at a speed of 12-16 m / s. At the same time, a reduced pressure is maintained at the cut of the nozzle 7 pos tons, and under the action of κοτοροιo a mixture of water and fish flows continuously into the mixing chamber 3 from the cavity of the filter 18. The flow of working water and the flow of water from the filter are mixed in the mixing chamber 3, exchange

energy and in the form of a total flow into the pipe 19.

Adjusting the mode of operation of the pump in order to establish a mode with maximum efficiency is made by changing the width of the nozzle 14,

Changing the size of the nozzle by rotating the shaft 12 in one direction or another. The rotation of the shaft 12 is transmitted to the associated gear 11, which (calls the rotation of the gear wheel 10, the rotation of the wheel 5)

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Sa 10 rotates the nozzle 7, simultaneously moving up or down due to the threaded connection 9 with a fixed nozzle 6. At the same time, the width of the nozzle decreases or increases.

Execution of the fish pump suction channel in the form of two telescopic pipes, one of which is movable and equipped with a gear wheel, ensuring its movement, allows you to create a fish pump, the external geometrical dimensions of which do not change when adjusting its mode of operation. There are no details in the fish pump and in suitable pipelines extra large voltages that could damage the pump itself or the piping. In comparison with the known, the proposed device is more reliable and can be used more widely.

The proposed fish pump has a simpler design. It has a simpler device for adjusting the mode of operation, in which only one gear is used, transmitting the movement from the shaft to the movable nozzle. This changes the width of the nozzle 14, which determines the value

head and flow of the pumped pulp fish - water. The design of the nozzle 14 is simple and at the same time allows all the energy of the working water supplied to the fish pump to transfer the pumped pulp, which allows you to work with great pressure, i.e. pump the slurry over long distances or pump at a high flow rate.

Claims (2)

Claim A fish pump, comprising a housing, a suction channel, a mixing chamber connected to the confuser and a diffuser, a device for adjusting the mode of operation, including a shaft with a gear mounted on it that is in engagement with the gear wheel, in order to simplify the design of the fish pump and increase the pressure and flow of the pumped pulp, the suction channel is formed by two telescopic nozzles interconnected by means of a thread, while one of the nozzles is rigidly connected to the pump casing, and the gear box eco reinforced in another pipe to move it. 1514299 FIG. 2