JPS6383500A - Conveying device for high viscous material - Google Patents

Abstract

PURPOSE:To reduce pipeline resistance by a large margin by vibrating the pipeline in the axial direction of the pipeline by an exciting device. CONSTITUTION:High viscous material supplied from a supply device 13 is discharged by a pump 15 and then let flow in a horizontal pipe 17 through the first coupling 23. As the horizontal pipe 17 is vibrated in the axial direction of a pipeline by an exciting device 35, the viscous material in the horizontal pipe 17 is decreased in contact resistance with the inner wall of the horizontal pipe 17 and moved along the horizontal pipe 17 to the outlet side. Further the viscous material flows in a vertical pipe 19 through the second coupling 25 and a bent pipe. As the vertical pipe 19 is excited in the axial direction of the pipeline by the exciting device 35, the viscous material in the vertical pipe 19 is decreased in contact resistance with the inner wall of the vertical pipe 19 and passed therethrough. This arrangement can reduce pipeline resistance by a large margin.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to a high viscosity substance conveying device for conveying high viscosity substances such as miso and clay.

[Conventional technology]

Conventionally, belt conveyors are often used to transfer high viscosity substances such as miso from a mixing tank to a fermentation tank.

However, when miso is transferred using a belt conveyor in this way, there is a problem that the water in the miso evaporates during the transfer, which is also undesirable from a sanitary point of view.

[Problems with conventional technology]

Therefore, it is being considered to use a pump to pressurize the miso into the pipe and transport the miso through the pipe, but in this case, the resistance in the pipe is extremely large, so the discharge pressure of the pump is reduced. If the pump discharge pressure is not increased, there will be a problem that the pipes will be clogged with miso, and if the pump discharge pressure is increased to prevent this, there will be a problem that the properties of the miso will be impaired.

[Purpose of the invention]

The present invention was made in order to solve the above-mentioned problems, and an object of the present invention is to provide a highly viscous material transport device that can easily transport highly viscous materials such as miso through a conduit. do.

[Means for solving problems]

The apparatus according to the present invention is a high viscosity substance transporting apparatus for transporting a high viscosity substance through a pipe using a pump, in which the pipe is vibrated in the axial direction of the pipe by a vibrator.

[Action of the invention]

In the 161Q feeding device for high viscosity substances of the present invention, the piping is vibrated in the axial direction of the piping by the vibrator, so that the contact resistance of the high viscosity substances in the piping with the inner wall of the piping is reduced by one movement. The pump moves it along the piping toward the outlet.

Therefore, the resistance of the pipe can be significantly lowered than in the past, the power required for the pump can be reduced, and highly viscous substances such as miso can be easily transferred through the pipe.

[Embodiments of the invention]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, details of the present invention will be described with reference to an embodiment shown in the drawings.

FIG. 1 shows an embodiment of the high viscosity substance conveying apparatus of the present invention, and in the figure, reference numeral 11 indicates a conduit through which high viscosity substances such as miso and clay are conveyed. On the inlet side of this conduit 11, a supply device 13 for supplying a substance at a height of 1' and a positive displacement pump 15 to which a suction pipe 15a is connected are arranged.

Therefore, in this embodiment, the pipe line 11 is composed of the horizontal pipe 17 and the vertical pipe 19.
and are connected by a bent pipe 21 fixed to an abutment F installed on the support part G as appropriate.

A first joint 23 is connected to the inlet side of the horizontal pipe 17, and a second joint 25 is connected to the outlet side.

Further, on the inlet side and the outlet side of the vertical pipe 19, a third tube is provided. A fourth joint 27, 29 is connected.

The horizontal tube 17 and the vertical tube 19 are each moved by a known vibrator 35 consisting of a pair of eccentric ways ( ) 31 and 33 and a motor (not shown) for rotationally driving the horizontal tube 17 and the vertical tube 19.
7 and vertical tube 19 in the axial direction.

In this vibrator 35, it is possible to change the excitation force using an internal balance weight, and it is also possible to change the excitation frequency via an inverter.

Further, the horizontal pipe 17 is supported by a vibration absorbing hanger 39 via a rubber roller 37.

FIG. 2 shows details of the joint 23.
is composed of a fixed tube 41 and a vibrating tube 43.

The fixed pipe 41 connects the flange portion 45 to the discharge pipe 4 of the pump 15.
It is connected to the flange portion 49 of No.7.

A vibrating tube 43 is inserted into the fixed tube 41 up to the center,
Between the tip of the vibrating tube t3 and the end face of the flange portion 49 of the discharge tube 47, there is a cylindrical vibration absorber having an annular groove 51a at the center outer periphery and having an inner diameter equal to the inner diameter of the discharge tube 47 and the vibrating tube 43. Rubber 51 is arranged.

In addition, the fitting gap between the vibration tube 43 and the fixed tube 41 has a 0-
The ring 53 is arranged, and the end surface of the vibration absorbing rubber 51 in contact with the vibration tube 43 has an escape groove 55 that communicates with the fitting gap.
A plurality of them are formed in the diameter direction of the vibration absorbing rubber 51 at appropriate intervals in the circumferential direction.

Brackets 57 and 59 are respectively fixed to the fixed tube 41 and the vibrating tube 43 by means of connection or the like, and both ends of the poles 61 are inserted through these brackets h57 and 59, respectively. This bolt 61 is connected to the vibration absorbing member 6
3 and a washer 65 to the bracket 57.59 by a double nut 67.
59 mutual spacing, i.e. fixed tube 41 and swing faJ tube 43
The axially fitted position with the shaft is maintained in a predetermined state.

Further, on the outer periphery of the vibrating tube 43, as shown in FIG.
A detent 71 inserted into the holder 9 is fixed by welding or the like.

Then, the flange portion 7 formed at one end of the vibration tube 43
3 is a flange portion 7 formed at one end of the horizontal rf1.1
5 by a clamp 77.

Note that the third joint 27 is similar to the first joint 27. The lower end flange part is connected to the upper flange 216 of the target tube 21, and the fourth joint 29 is a bracket fixed to the fixed tube 11. 57a has a large diameter, and the outer periphery of the bracket 57a is appropriately connected to the support part 9.
Since it is configured almost the same as the joint 23 except that it is fixed to the joint 23, a detailed explanation will be omitted.

FIG. 4 shows details of the joint 25.
is composed of a fixed tube 79 and a vibrating tube 81. The fixed tube 79 is sold with the flange portion 83 connected to the lower flange portion 21b of the bent tube 21. A vibrating tube 81 is inserted into the fixed tube 79 up to the center portion 1, and an annular groove 85a is provided on the outer periphery of the center portion between the tip of the vibrating tube 81 and the end surface of the lower flange portion 21b of the bent tube 21. , inner diameter is horizontal pipe 1
7° Vibration tube 819 A cylindrical vibration absorbing rubber 85 having the same inner diameter as the bent tube 21 is arranged. Further, an O-ring 87 is arranged in the fitting gap between the vibrating tube 81 and the fixed tube 79.

A flange portion 89 formed at one end of the vibration tube 81
is connected to a flange portion 91 formed at the other end of the horizontal tube 17 by a clamp 93.

In the high-viscosity substance conveying apparatus configured as described above, the high-viscosity substance supplied from the supply device 13 is discharged by the pump 15, and then flows into the horizontal pipe 17 through the first joint 23. Since the horizontal pipe 17 is vibrated in the axial direction of the pipe by the vibrator 35, the contact resistance of the high viscosity substance within the horizontal pipe 17 with the inner wall of the horizontal pipe 17 is reduced, and Move along to the exit side.

The moved high viscosity substance is transferred to the second joint 25 and the bent pipe 2.
1 and flows into the vertical pipe 19. Since this vertical pipe 19 is vibrated in the axial direction of the pipe by the adding machine 35, the high viscosity substance in the vertical pipe 19 is removed from the horizontal pipe 1.
As in case 7, the contact resistance with the inner wall of the vertical tube 19 is reduced and the tube moves along the vertical tube 19 toward the outlet side.

That is, in the high viscosity substance conveying apparatus configured as described above, since the horizontal tube 17 and the vertical tube 19 are vibrated in the axial direction by the vibrator 35, the horizontal tube 17 and the vertical tube 1 are vibrated in the axial direction.
The high viscosity substance in the pipe 9 is moved to the outlet side by the pump 15 in the horizontal pipe 17 and the vertical pipe 19 in a state where the pipe resistance is reduced.

Therefore, in the highly viscous substance conveying device configured as described above, the resistance of the conduit 11 can be significantly lowered than before, so the capacity of the pump 15 can be reduced, for example, by about 40% compared to the conventional one. Become.

Furthermore, when using the same pump 15, the pipe line 11
The distance can be significantly extended compared to conventional methods.

In addition, in the high viscosity substance conveying apparatus configured as described above, the pipe line 11 is divided into a plurality of parts, these are connected via the first to fourth joints 23, 25, 29, and the inside of these joints is Since the vibration pipe is connected to the stationary pipe in a buffering manner in the axial direction through the vibration absorbing rubbers 51, 85, 53, 87, and 63 and the vibration absorbing member 63, resonance of the pipe line 11 can be prevented. This allows the horizontal tube 17 and the vertical tube 19 to be effectively vibrated only in the axial direction.

Furthermore, since the relief groove 55 is formed in the vibration absorbing rubber 51, high viscosity substances are removed from between the vibration tube 43 and the vibration absorbing rubber 51.
Even when leaking to the ring 53 side, this leaked high clay material is returned to the pipe line 11 through the escape groove 55 and does not leak out from the O-ring 53.

〔Effect of the invention〕

As described above, according to the present invention, since the piping is vibrated in the axial direction of the piping by the vibrator, the resistance of the piping can be significantly lowered than before, and there is no need to increase the transport pressure of the pump.
It has the advantage that the required power is small, and the conduit allows highly viscous substances such as miso to be easily transported without adversely affecting the soil.

[Brief explanation of the drawing]

Fig. 1 is a side view showing an embodiment of the high viscosity substance conveying device of the present invention, Fig. 2 is a vertical sectional view showing details of a joint placed on the inlet side of the piping shown in Fig. 1, and Fig. 3 2 is a top view showing the vicinity of the detent shown in FIG. 2, and FIG. 4 is a vertical cross-sectional view showing details of the joint disposed on the outlet side of the piping shown in FIG. 1. 17...Horizontal pipe, 19...Vertical pipe, 35...F
i machine, 51.85... vibration absorbing rubber.

Claims (2)

[Claims] (1) In a high viscosity substance conveyance device that transports a high viscosity substance through a pipe using a pump, the pipe is vibrated in the axial direction of the pipe by a vibrator, and the contact resistance between the high viscosity substance in the pipe and the inner wall of the pipe is A conveying device for high viscosity substances, which is characterized by reducing viscosity. (2) The high viscosity substance conveying device according to claim 1, wherein the pipe is divided into a plurality of pipes, and each pipe is connected via a vibration absorbing rubber.