JP2000309424A - Fluid transport device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To transport fine particles in a long distance, by using a pump. SOLUTION: An injection pump 7 taking in fine particles from a supply source 5 and delivering into a transport path 3 is provided, and nozzles 10 injecting air into the transport path 3 in its halfway are provided in a plurality of places. Compressed air is supplied from a compressor 20 to each nozzle 10, when the air is delivered into the transport path 3 from the nozzle 10, a helical flow of air along an inner surface of the transport path 3 is generated, movement of the fine particles is promoted, and transport force is reinforced.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fluid transport device for pumping fluid such as powder, granules, slurry, and liquid by a pump.

[0002]

2. Description of the Related Art Conventionally, pneumatic transportation utilizing a flow of air has been performed in the case of transporting a flowable solid fluid such as powder or granules such as cement and grains. this is,
As shown in FIG. 6, powder and the like are supplied from a hopper 1 to a transport path 3 by a discharge screw 2, compressed air is sent using a blower 4 such as a roots blower, and the powder and the like are blown into the transport path 3 together with air. The separator is provided on the outlet side of the transport path 3 to separate and extract the powder and the like from the air flow. Then, during transportation, for example with respect to the powder 1 m ³ is required air 10 m ^3,
This can transport a distance of about 1 km.

[0003] When a liquid fluid such as a slurry or a liquid is transported, the fluid is transported by applying pressure using a pump by utilizing these fluidities. In particular, a slurry pump or a squeeze type pump is used as a pump suitable for transporting slurry such as muddy water or water mixed with cement.

[0004]

As described above, the pneumatic transportation requires a separator in addition to the blower, and is not suitable for transporting a fluid such as cement to a construction site having a limited space. Further, in order to transport a longer distance, the amount of air to be sent must be increased, and the size of the blower increases. On the other hand, transport using a pump is suitable for use on a construction site because a separator is not required.However, it is possible to transport a liquid fluid such as a slurry, whereas powder or granular material is not used. Can not be transported. Further, when transporting a long distance, the output of the pump must be increased, and the pump must be increased in size and improved in performance.

[0005] In view of the above, the present invention can transport not only liquid fluids but also solid fluids such as powders and granules when transporting by a pump that does not require a separator. An object of the present invention is to provide a fluid transport device that can be transported.

[0006]

According to the present invention, a fluid is mainly sent by an injection pump, but a fluid such as air is added as an auxiliary means of transportation in the middle of a transport path, and is used for a long distance. In order to transport the gas, the transport power is insufficient on the way with the pump alone. Therefore, the transport power is enhanced by injecting another fluid into the transport path from the outside. The use of air as another fluid is optimal from the viewpoint of cost and safety.

[0007] The transporting force enhancing means for injecting air from the outside into the transporting path to promote the movement of the fluid includes a nozzle interposed in the transporting path and an air supply unit for supplying air to the nozzle. The nozzles are arranged at a plurality of locations in the transport path, and the amount of air supplied from the air supply unit is adjusted for each nozzle according to the amount of fluid transported. That is, when air is injected from the oblique direction of the transport path along the flow of the fluid in the transport path, the so-called outer peripheral surface of the flux, a spiral air flow is generated on the outer peripheral surface of the flux. Thereby, the fluid transporting power can be enhanced.

[0008] The nozzle is provided with a plurality of discharge ports in a cylinder interposed in the transport path, and the discharge ports penetrate the peripheral wall of the cylinder and are inclined in a direction intersecting the axial direction (transport direction). It is formed. For this reason, air is discharged obliquely to the transport direction, and a spiral airflow is formed along the inner surface of the transport path, so that the fluid can be moved efficiently and the transport power can be improved.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG.
Shown in This fluid transport apparatus transports powder through a transport path 3 from a supply source 5 having a hopper storing powder as shown in FIG. 6 to a destination 6 such as a tank at a construction site or a factory. And an injection pump 7 that takes in powder from a supply source 5 and feeds the powder into the transport path 3. As the injection pump 7, a well-known pump suitable for transporting a slurry or liquid such as a slurry pump, a squeeze type pump, and a reciprocating pump is used. The transport path 3 is formed by connecting a plurality of transport pipes 3a via respective joints, and a material is selected from mild steel, stainless steel, cast steel, and the like according to a substance to be transported. The pipe diameter of 3a is selected. It is to be noted that a branch pipe is interposed in the middle of the transport path 3 and the transport path 3 is branched to enable transport to a plurality of destinations.

In order to enable long-distance transportation,
There is provided a transporting force increasing means for injecting air from the outer periphery of the transporting path 3 to pump the fluid. As shown in FIG. 2 to FIG. 4, the transport power enhancing means includes a plurality of nozzles 10 interposed in the transport path 3 and injecting air into the transport pipe 3 a from the outside.
And an air supply unit 11 for supplying air to each nozzle 10.

The nozzle 10 has a cylindrical body 12 having the same inner diameter as the transport pipe 3a, and a plurality of discharge ports 13 penetrating the peripheral wall thereof. The cylindrical body 12 is adjacent to the transport pipe 3a.
It is connected so as to be detachable by a joint 15 via a collar 14 therebetween. A thick step 16 is formed on the outer surface of the cylindrical body 12 so that a hole penetrating obliquely from the outer surface to the inner surface of the cylindrical body 12 can be formed. An oblique hole toward the inner surface is formed, which serves as a discharge port 13, and is 90
It is arranged at equal intervals of degrees. Thereby, the discharge port 13
The air is blown out from the inside along the inner surface, and the transporting force in the portion along the inner surface where the transporting force is lowest is increased. As shown in FIG. 5, if the direction of the discharge port 13 is slightly inclined in the circumferential direction with respect to the transport direction (axial direction), air is discharged obliquely with respect to the transport direction, and along the inner surface. A helical airflow is formed, which can further increase the transport power. In this case, the angle of inclination is optimally 30 degrees.

At the inlet side of each discharge port 13, a connecting pipe 1
7 is screwed, one end of which is projected outside to
A tube 18 is connected. A connection pipe 17 is screwed into the hole formed in the same manner as described above so as to penetrate the cylinder 12, one end of which is connected to the T-tube 18, and the other end reaches the center of the cylinder 12, Blow air into the center of 12.

Each of the T-tubes 18 has an annular hose 19.
And the hose 19 is connected to the air supply unit 11. The air supply unit 11 includes one compressor 20 and an injection pipe 21 that connects the compressor 20 to the hose 19 of each nozzle 10, and supplies air to each nozzle 10 at the same time. In addition, when the transport path 3 extends over a long distance, the injection pipe 21 becomes longer, so that the compressor 20 may be provided for each nozzle 10.

In the injection pipe 21, a check valve 22, an electromagnetic valve 23, and an adjustment valve 24 are provided for each nozzle 10 in this order from the nozzle side. Adjustment valve 24
Is used to adjust the amount of air supplied to the nozzle 10, and is opened and closed by operating a lever to determine the amount of air. The electromagnetic valve 23 is an opening / closing valve controlled by a control device that controls the transport device, and is turned on to inject air when it is necessary to increase the transport force according to the transport amount of the powder. The check valve 22 is an injection pipe 2 for the powder to be transported.
1 is prevented from entering. It should be noted that the adjustment valve 24 and the electromagnetic valve 23 may be integrated into a flow adjustment valve, which may be drive-controlled.

In the above-described transport apparatus, when the injection pump 7 is driven, powder is taken in from the supply source 5 into the transport path 3 and is extruded. As described above, the powder moves in the transport path 3, but if the transport distance is long, the transport power is insufficient with the injection pump 7 alone. Therefore, air is injected into the transport path 3 from the nozzles 10 arranged in the transport path 3. The air pressure to be injected is 2 kg / cm ² ,
If it is too high, more air will be mixed into the powder and it will be necessary to separate it, so this is appropriate to increase transport power.

When air is injected into the transport path 3, a spiral air flow is formed along the inner surface of the transport pipe 3a, so that the powder moving slowly near the inner surface of the transport pipe 3a is moved. The body is swept away and the transport power is increased, and the powder is pumped at an increased moving speed. By repeating this, the powder is transported farther, and transported to the destination 6 is performed.

Therefore, when the powder is to be transported by the injection pump 7 used for transporting the liquid,
By arranging such nozzles 10 at a plurality of locations in the transport path 3, powder can be transported over long distances without clogging on the way, for example, transporting only 1 km but transporting 2 km to 3 km is possible. Can be.

It should be noted that the present invention is not limited to the above-described embodiment, and it goes without saying that many modifications and changes can be made to the above-described embodiment within the scope of the present invention. In the above-described embodiment, the powder is transported. However, the above-described transport power enhancing means may be applied to transport a fluid such as a granular material or a slurry such as muddy water or a liquid. In the case of transporting a slurry or a liquid, the number of nozzles to be installed can be reduced as compared with the case of transporting powder or the like. At this time, instead of injecting air from the nozzle, nitrogen,
A different fluid, such as oxygen or another gas such as gas or a liquid such as water, may be injected, or if the transported material is a liquid fluid, the same fluid may be injected.

[0019]

As is clear from the above description, according to the present invention, another fluid such as air is injected from the nozzle into the fluid transport path to assist the movement, and therefore, the conventional fluid such as slurry and liquid is used. It is possible to transport the powder and the granular material by using the pump which can be transported only. Therefore, the amount of supplied air is smaller than that in the case of pneumatic transportation, so that a separator is not required, and this transportation apparatus is suitable for use in a place where the installation space is small, such as a construction site.

Further, by disposing the nozzles at a plurality of locations in the transport path, the transport power is enhanced each time, so that the nozzle can be transported over a long distance and the destinations are dispersed in a plurality. It can be transported efficiently.
Therefore, it is not necessary to increase the size and performance of the pump, and there is an effect that a small pump may be used.

[Brief description of the drawings]

FIG. 1 is an overall configuration diagram of a fluid transport device according to an embodiment of the present invention.

FIG. 2 is a front view of a nozzle.

FIG. 3 is a side view of a nozzle.

FIG. 4 is a sectional view of a nozzle.

FIG. 5 is a front view of a nozzle having another form of discharge port.

FIG. 6 shows a conventional pneumatic transportation source;

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 3 Transport path 5 Supply source 7 Injection pump 10 Nozzle 11 Air supply part 12 Cylindrical body 13 Discharge port 20 Compressor 21 Injection pipe

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[Procedure amendment]

[Submission date] December 28, 1999 (1999.12.
28)

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Claims

[Correction method] Change

[Correction contents]

[Claims]

Claims (5)

[Claims] 1. A fluid transport device for pumping a fluid to a destination by a pump via a transport path to a destination, wherein another fluid is injected from the outside into the transport path to enhance the movement of the fluid. A fluid transport device, comprising: 2. An infusion pump which takes in a powdery fluid and feeds it into a transport path, and a transport power enhancing means for injecting air from the outer periphery of the transport path and pumping the fluid in the transport path. Characteristic fluid transport device. 3. The transporting force increasing means comprises a nozzle interposed in a transporting path and an air supply unit for supplying air to the nozzle, and discharges air obliquely to a transporting direction to form an outer periphery of the fluid. 3. The fluid transport device according to claim 1, wherein the direction of the discharge port of the nozzle is set such that a spiral air flow is formed on the surface. 4. A nozzle according to claim 1, wherein nozzles are arranged at a plurality of positions in the transport path, and an adjusting section is provided for each nozzle to adjust an amount of air supplied from an air supply section in accordance with a transport amount of the fluid. The fluid transport device according to claim 3, wherein 5. A nozzle for injecting air into a transport path for pumping a fluid by a pump to promote the movement of the fluid, wherein a plurality of discharge ports are provided in a cylinder interposed in the transport path. Is provided, and an annular air supply connection pipe communicating with each discharge port is provided, and the discharge port is formed to penetrate the peripheral wall of the cylindrical body and to be inclined in a direction crossing the axial direction. Nozzle used in a fluid transport device.