KR200399161Y1 - Fish pump - Google Patents

Abstract

The present invention relates to a high efficiency fish transfer pump capable of smoothly pumping fish without damaging the fish.

The present invention, the impeller 22 is installed in the internal impeller chamber 21 of the housing 20, the rear side of the housing 20 is provided with a drive motor 27 for rotating the impeller 22 In this case, the induction pipe 30 having a structure gradually widening toward the impeller 22 and coupled to the front center portion of the housing 20, and the discharge portion for transmitting the sucked fish to the side of the housing ( 35) is provided and configured.

In addition, the induction pipe 30 may have a structure in which the suction port 31 is bent at a gentle angle, and a water supply part 34 is formed at a side of the induction pipe 30 to supply water toward a fish suction direction. Can have

In addition, the discharge port 36 is a direction of the discharge path 37 and the discharge port 36 leading from the impeller 22 to the discharge port 36 of the impeller 22 while the origin of the center of the impeller 22 A number of circles passing through the space between the outer diameter and the inner diameter of the impeller chamber 21 are circumscribed to form a direction parallel to the direction in which the tangent of the impeller 22 rotates at the contact portion. In addition, the impeller 22 is installed to be ubiquitous so as to gradually widen in the direction of starting the delivery of the fish in the housing, and to inject high pressure water toward the impeller chamber 21 on the opposite side of the delivery path 37 The water spray nozzle 39 is provided.

The present invention of the above configuration, the vacuum pressure of the impeller chamber for the initial pumping is to be pumped through the pick-up through the water pump, and also has the advantage that the volume is minimized because there is no need for a vacuum pump and suction chamber as in the prior art According to the attachment direction of the induction pipe, the direction of the transfer pipe is freely variable according to the conditions of the installation space, and the discharge port direction of the discharge part is also variable according to the installation angle of the housing, there is an advantage that can be easily installed in a narrow space.

In addition, the present invention assists the transport of fish by continuously spraying water at a high pressure in the feed direction of the fish sucked into the impeller through the water supply in the induction pipe, while the water spray nozzle installed in the impeller chamber is directed to the outflow direction of the fish. As water is applied by pressure, the reverse flow of the fish is prevented, and the conveying force of the fish is improved, and the guide pipe is extended in the direction of the impeller chamber. The impeller is ubiquitous in the impeller chamber, and the water flows through the impeller in the opposite direction to the fish delivery direction of the impeller chamber, so that the fish flowing back along the impeller for the blocking or the fish delivery As a result of its auxiliary function, the efficiency of fish delivery can be greatly improved while minimizing damage to fish. There is a win.

Description

Fish Pump

The present invention relates to a pump for transporting fish such as anchovy, and more specifically, to simplify the structure of the pump and the variable inflow and outflow of the fish can be easily installed in a narrow installation space, when pumping fish The present invention relates to a fish transfer pump that can minimize damage to the fish while improving pumping capacity through the improvement of the discharge path with the backward flow prevention and the natural discharge direction, and the angular improvement of the impeller blades.

The general fish feed pump includes a transfer pump (1) having an impeller (4) providing suction and delivery power for suctioning and delivering fish, and a suction pipe (7) installed in communication with the transfer pump (1) to suck fish. And a delivery pipe 8 and an impeller 4 for delivering fish from the transfer tank 1.

The pre-registered registration No. 20-0347592 also has a structure of a fish transfer pump, looking at the structure, as shown in Figure 1a, 1b is a conventional pre-registered fish transfer pump (fish pump) is a pedestal (11) It is supported by), the suction chamber 2 is installed in the upper part of the impeller 4 is connected to the suction pipe (7), the side of the impeller (4) for sending the fish transported by the impeller (4) A sending part is formed, and the sending part 8 is connected to the sending part 3.

An incidence part 6 having a narrow incidence angle is formed in the lower portion of the suction chamber 2 flowing into the impeller 4, and an exit part 9 inclined narrowly in the traveling direction is formed at the side of the impeller 4. Formed. In addition, the suction pipe 7 and the discharge pipe 8 of the discharge part 3 are provided with one-way valves 12 and 13 which open and close only in one direction, and the upper part of the suction chamber 2 is not shown in the drawing. The vacuum suction port 10 is connected to the vacuum pump is formed.

In addition, the impeller 4 forms a suction path 14 in the upper portion thereof, and is formed by the blade pieces 15 and 15 'formed in a vortex from the suction path 14 to open laterally. Is provided.

When pumping fish with the conventional fish feed pump having the above configuration, the hydraulic motor 5 is operated while vacuuming the inside of the suction chamber with the vacuum pump through the vacuum suction port to start the pumping of the fish. When the fish is introduced by the operation and suction suction starts, the operation of the vacuum pump is stopped and pumping by the impeller 4 proceeds.

The pumped fish flows into the suction chamber 2 and then passes through the incidence portion 6 of the upper and lower straits into the impeller 4 and discharges laterally. At this time, since the delivery unit 3 is formed on the side of the impeller 4, the fish is transferred to the delivery pipe 8 through the delivery unit 3.

However, since the conventional fish transfer pump has a suction chamber 2 at the top, it is always possible to install only the suction chamber 2 upright on the upper part of the pedestal 5, and to install the suction suction 2 at the top. As the height of the seal 2 increases and the volume increases to occupy a lot of installation space, there is a disadvantage that a separate unnecessary construction is necessarily accompanied in order to secure a space for the fish transfer pump to be installed in a place where the installation space is narrow. have.

In addition, the fish flows into the suction chamber (2) and then the transport path to the impeller (4) has a structure in which the direction of the fish inflow path is sharply changed as shown in the drawing, the incident part (6) As the narrowness in the direction of the impeller (4) causes a disturbance in the transfer of fish due to the bottleneck phenomenon, this causes a closed end that is damaged by hitting the inner wall of the suction chamber (2) or the incidence (6). . Also in the delivery section 3, as shown in FIG. 1B, the direction of the delivery section 3 is formed in the axis and normal direction of the impeller, irrespective of the rotational direction of the impeller 4 and the delivery direction of the fish. The outgoing fish hit the inner wall of the outgoing delivery unit 3 opposite to the outgoing ship. In particular, as the check valve 12 'is installed at the two connections between the suction pipe 7 and the discharge pipe 8, the check valve 12' is shocked once on the suction side check valve 12 and is again supplied to the check valve 12 '. In the process of passing the impacted fish such as shock passing through the two check valves (12, 12 '), the damage of the fish is intensified, as well as there is a closed end that acts as an obstacle to the transfer of fish.

In addition, in the conventional fish feed pump, as shown in FIG. 1B, the impeller 4 is positioned at the center of the impeller chamber, and thus an impeller 4 is formed between the impeller 4 and the inner wall of the impeller chamber. When the fish are discharging according to the rotation of the fish, the fish are sent not only in the direction of the discharging part 3 but in all directions and the fish conveying force in the discharging path 3 is distributed, resulting in a decrease in the conveying efficiency of the fish, and the discharging of the fish. Due to the rotational force of (4), the phenomenon of rotating with the impeller is caused, and the damage of the fish is intensified, as well as the pumping pressure and the feeding efficiency of the fish.

In addition, the conventional fish transfer pump is required for the operation of vacuuming the inside of the suction chamber (2) through the vacuum pump shown in the drawing in the initial stage for pumping the fish, the cost increase of the product and the fish according to the addition of the vacuum pump According to the installation of the transfer pump, there was a need for securing an unnecessary installation space or securing an unnecessary space for securing an installation space.

The present invention was devised to solve the above-mentioned conventional problems, the purpose of which is to remove the inlet chamber mounted on the conventional fish transfer pump, instead of attaching the suction feed induction pipe of the structure extending in the impeller direction While reducing the overall volume of the fish feed pump, the delivery part is also formed to be inclined in the direction in which the fish is sent out from the impeller to match the natural feeding direction of the fish, thereby minimizing the damage of the fish due to the smooth transfer of the fish and pumping the fish. It is to increase the power.

Another object of the present invention is to provide an initial pumping of the fish transfer pump through the pick-up of the water supply unit together with the removal of the inlet chamber, which has been installed in the conventional fish transfer pump, as described above. The fish transport pump can be miniaturized.

In addition, another object of the present invention is to make it possible to easily install even in a narrow installation space by minimizing the volume as described above and allowing the installation direction to be freely selected.

In addition, another object of the present invention, by continuously spraying water in the feed direction of the intake fish to assist the transfer of fish to increase the suction transfer effect of the fish.

 In addition, another object of the present invention is to install the impeller so that the discharging direction of the fish in the impeller chamber toward the exit direction of the discharge portion, while water in the discharging direction of the fish on the inner wall of the impeller chamber opposite to the fish discharging direction The high-pressure injection blocks the fish flowing back along the impeller and at the same time increases the delivery effect of the fish.

Hereinafter, with reference to the accompanying drawings the configuration of the subject innovation will be described in detail.

Figure 2 is a perspective view showing the structure of the fish transfer pump according to the present invention, Figure 3 is a cross-sectional view showing the structure of the fish transfer pump according to the present invention, Figure 4 is a longitudinal sectional view of the fish transfer pump according to the present invention, Figure 5 is another embodiment of the impeller fish feed pump according to the present invention.

As shown in the drawings, the fish transfer pump of the present invention is basically equipped with an impeller 22 in the internal impeller chamber 21 of the housing 20, the front and rear open, the impeller on the rear side of the housing 20 Bolt the cover 25 to block the seal 21 and firmly couple the drive motor 27 to the outside of the cover 25 with a bolt and rotates the impeller 22 through the shaft hole 26 formed in the center portion The impeller 22 can be rotated at high speed by axially coupling with the drive motor 27 (mostly composed of a hydraulic motor).

In addition, the front center portion of the housing 20, that is, the suction portion center portion of the impeller 22, as shown in Figures 2 and 3, the trumpet-shaped fish induction pipe extending in the direction of the suction portion of the impeller 22 ( 30) is bolted. At this time, the beginning of the fish induction pipe 30, that is, the suction port 31 may be matched with the axial direction of the impeller 22, but the fish connected by giving a sloping direction gently from the axial direction of the impeller according to the site conditions It is preferable to prevent the installation space in the axial direction from being increased by the suction feed pipe 32. Of course, it is essential to minimize the phenomenon that the fish hit the wall surface of the guide pipe 30 when the fish is transported so that the direction of the guide pipe 30 is gentle, the direction of the guide pipe 30 is the housing 20 When combined with the), it is possible to assemble and adjust by selecting the proper direction according to the site conditions. In addition, a check valve 33 which opens and closes only in the direction of the impeller 22 is installed at a connection portion with the suction port 31 of the induction pipe 30, that is, the suction transfer pipe 32.

In addition, the side of the induction pipe 30 is provided with a water supply part 34 for supplying water to supply the pick-up material to the impeller chamber 21 at the initial stage of pumping, so that the vacuum necessary for smooth pumping of the fish with only the rotational suction force of the impeller 22 is provided. To get it. In addition, the high-pressure spraying is possible through the nozzle to the water supply part 34, so that the high-pressure spraying of water in the conveying direction of the oil transported by the pumping operation, together with the function of supplying the necessary grease during the initial pumping, forces to convey the fish. It is supposed to add.

On the other hand, at the side of the housing 20, a delivery portion 35 for sending the sucked fish to the delivery delivery pipe 38 is formed. That is, as shown in Figs. 4 and 5, the structure of the impeller 22 is designed to suck the fish into the center portion and to discharge the fish to the side. The discharge part 35 has a structure generally formed integrally with the housing 20, and the direction of the discharge path 37 and the discharge port 36 extending from the impeller 22 to the discharge port 36 is an impeller 22. Tangential to the direction of the direction of rotation of the impeller 22 at its contact portion while externally contacting numerous circles passing through the space between the outer diameter of the impeller 22 and the inner diameter of the impeller chamber 21 with the center of It is intended to be in parallel with this drawing direction. Due to the direction of the delivery path 37 and the delivery port 36, the damage to the fish can be minimized because the factors acting as obstacles such as bottlenecks or protrusions during the delivery of the fish are minimized.

On the other hand, the impeller 22 is generally so that the impeller shaft 24 is located in the center of the housing 20, in the present invention, as shown in Figure 4 so as to gradually widen in the direction in which the delivery of fish ( a <a '), and the water spray nozzle 39 which injects a high pressure water toward the discharge port 36 is provided in the inner wall part of the impeller chamber 21 on the opposite side to the said delivery path 37 especially. The water sprayed by the water spray nozzle 39 blocks the flow of fish to be discharged toward the outlet 36 through the impeller 22 by the rotation of the impeller 22 through high pressure water pressure. At the same time, it is designed to increase the transfer efficiency by adding force to the transfer of fishes sent out in the forward direction along with the function of pushing the transfer out in the direction of the discharge port 36.

In addition, one side of the housing 20 is provided with a support 29 for fixing the present invention fish transfer pump to the support. This may be fixed, but may have a structure that can be changed according to the characteristics of the installation space. That is, as shown in FIG. 6, a plurality of tabs 28 having predetermined intervals are formed at several circumferences of the housing 20, and a separate support part 29 is bolted to the tabs 28. It is configured to change the position of the support portion 29 according to the conditions of the site installation space and bolted to the housing 20, and then firmly fixed to the support portion, that is, the base portion.

In addition, even in the structure of the impeller 22, the fish may be damaged by the inlet portion 23b of the impeller blade 23 shown in a straight line as shown in FIG. In order to minimize this, the angle of the inlet portion 23a of the impeller wing 23 is configured to form a gentle curve as shown in FIG. 5.

Looking at the operating state of the fish transfer pump of the present invention are as follows.

First, the filling material is filled in the impeller chamber 21 and the induction pipe 30 through the water supply part 34 inside the induction pipe 30, and then the impeller 22 is rotated to discharge the picking material. This catches the fish from the suction feed pipe (32). If the fish begins to flow into the impeller chamber 21 while the supply of the meet water of the water supply part 34 is continued, then the pumping of the fish proceeds continuously without the meet water. In this case, the water supply unit 34, which supplies the pick-up material for the initial pumping, may stop the water supply, but may continuously apply high pressure to the fish to increase the transport efficiency by applying an auxiliary force to the transport of the fish.

Since the sucked fish has a structure in which the shape of the guide tube 30 is widened like a trumpet as it moves toward the impeller 22, there is no part acting as a resistance to the fish's transportation, and thus the fish is smoothly sucked and transferred. Damage does not occur or is minimized.

Meanwhile, the impeller 22 sucks the fish into the center portion and discharges the fish in a direction perpendicular to the suction direction. In this process, the fish is discharged in all directions but extends in the direction of the outlet 36, and in the other direction. Although there is a little space but is blocked by the inner wall of the housing 20 eventually the fish is discharged toward the discharge port (36).

The discharged fish is pumped along the delivery path 37 to the delivery port 36. In this process, the direction of the delivery path 37 and the delivery port 36 coincides with the delivery direction of the fish. At the same time, there are no obstacles to the transport of fish, so there is no damage or minimal damage.

On the other hand, the fish flows backward in the opposite direction through the fish delivery direction by the rotational force of the impeller 22 and by the continuous pumping action of the impeller 22 in the process of sending the fish through the delivery path 37 to the delivery port 36. There is. In this case, the fish flowing back may collide with the inner wall of the impeller chamber 21, and may be damaged. However, the water jet nozzle 39 installed in the impeller chamber 21 opposite to the discharge direction may be damaged at a high pressure toward the fish flowing backward. By spraying the water of the fish, the reverse flow of the fish can be blocked and transferred to the outlet 36, and the power can be further improved as the force is applied to the transfer of the fish sent in the direction of the outlet 36. .

As described above, the fish transfer pump of the present invention

Instead of the hydraulic chamber in the conventional fish feed pump attached to the suction feed guide tube of the structure extending in the direction of the impeller, the pumping of the impeller chamber necessary for the initial pumping of the fish through the pick-up through the water pump is made to As there is no need for a vacuum pump, there is an advantage that the volume is minimized.

In addition, as described above, the overall volume of the fish feed pump is reduced, and the direction of the feed pipe is freely variable according to the installation space conditions, and the discharge port direction of the delivery unit is also variable according to the housing installation angle, so that it is easy to use in a narrow space. There is an advantage that can be installed.

In addition, the present invention assists the transport of fish by continuously spraying water at a high pressure in the feed direction of the fish sucked into the impeller through the water supply in the induction pipe, while the water spray nozzle installed in the impeller chamber is directed to the outflow direction of the fish. As water is applied by pressure, the reverse flow of the fish is prevented, and the conveying force of the fish is improved, and the guide pipe is extended in the direction of the impeller chamber. As it is matched, there is an advantage that the damage of the fish is minimized or minimized as well as the pumping force is improved.

In addition, the impeller is ubiquitous in the impeller chamber, and as described above, the high-pressure spraying water on the inner wall of the impeller chamber on the opposite side of the fish delivery direction results in the blocking effect of the fish flowing back along the impeller and the delivery efficiency of the fish. This has the advantage of being elevated.

Figure 1a, 1b is a cross-sectional view showing the structure of a conventional fish transfer pump.

Figure 2 is a perspective view showing the structure of the fish feed pump according to the present invention.

Figure 3 is a cross-sectional view showing the structure of the fish transfer pump according to the present invention.

Figure 4 is a longitudinal sectional view of the fish transfer pump according to the present invention.

Figure 5 is another embodiment of the impeller of the fish transfer pump according to the present invention.

Figure 6 is an embodiment of the pedestal of the fish transfer pump of the present invention.

*** Explanation of symbols for the main parts of the drawing ***

20-housing 21-impeller chamber

22-Impeller 23-Impeller Wings

24-Impeller Shaft 25-Cover

26-Shaft hole 27-Drive motor

28-Tab 29-Base

30-guide tube 31-suction port

32-Suction transfer pipe 33-Check valve

34-Water Supply Unit 35-Discharge Unit

36-Outlets 37-Outlets

38-Delivery pipe 39-Water spray nozzle

Claims (8)

In the internal impeller chamber 21 of the housing 20 is provided with an impeller 22, the rear side of the housing 20 is provided with a drive motor 27 for rotating the impeller 22, Induction pipe 30 having a structure gradually widening toward the impeller 22 and coupled to the front center portion of the housing 20, Fish transport pump, characterized in that the side portion of the housing 20 is provided with a discharge portion 35 for transmitting the sucked fish. The fish feed pump according to claim 1, wherein the induction pipe (30) inlet (31) is bent at a gentle angle. According to claim 1 or claim 2, Fish feed pump characterized in that the water supply portion 34 for supplying water toward the fish suction direction on the side of the induction pipe 30 is formed The fish feed pump according to claim 1, characterized in that a check valve (33) is provided which opens and closes only in the direction of the impeller (22) at the suction port (31) of the induction pipe (30). According to claim 1, wherein the discharge port 36, the direction of the discharge path 37 and the discharge port 36 leading from the impeller 22 to the discharge port 36 while the center of the impeller 22 as the origin It is made to be parallel to the direction in which the tangent of the direction of rotation of the impeller 22 at the contact portion while circling with a myriad of circles passing through the space between the outer diameter of the impeller 22 and the inner diameter of the impeller chamber 21. Fish transfer pump. The fish transfer pump according to claim 1, wherein the impeller (22) is ubiquitous so as to widen gradually in a direction in which the delivery of fish starts in the housing. The water spray nozzle (39) according to any one of claims 1, 5 and 6, wherein a water spray nozzle (39) for injecting high pressure water toward the impeller chamber (21) opposite to the discharge passage (37) is provided. Fish transfer pump. The method according to claim 7, wherein a plurality of tabs 28 are formed at regular intervals around the lower portion of the housing 20, and a separate support part 29 is bolted to the tabs 28, so as to provide a site installation space. Fish transport pump, characterized in that for bolting to the housing 20 by changing the position of the support portion 29 to fit.