JPH0446809Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to an improvement of an in-line emulsifying and dispersing machine in which a dispersion chamber is arranged in the axial direction of a drive motor.

[Prior Art] Such an emulsifying and dispersing machine has conventionally been configured as follows. That is, a dispersion chamber H is attached to a bearing B connected to a drive motor M via a coupling C and a shaft seal S (FIG. 3). A dispersion chamber H is attached to a bearing B attached to a drive motor M and a shaft seal S (connected by a coupling C) (Fig. 4). A dispersion chamber H is attached to a bearing B, a speed increaser G, and a shaft seal S connected to a drive motor M via a coupling ring C (Fig. 5). Bearing B, speed increaser G, and shaft seal S attached to drive motor M
Attach dispersion chamber H to (Figure 6).

This resulted in the following drawbacks.

(1) Since the components are arranged in the axial direction, it becomes longer in the axial direction.

(2) Bearing B supports the shaft of the cantilever beam, so a sufficient distance between the bearings is required, making it longer in the axial direction.
In addition, when the load is large or when processing high temperature liquids, the bearings are water-cooled and cooling piping is required.

(3) If the centering accuracy of the coupling ring C is poor, vibration and excessive load will be applied to the bearing B, so the centering work requires skill.

(4) Periodic inspection and replacement of the lubricating oil of gearbox G is required. Furthermore, if lubricating oil or mist leaks, it will contaminate the surrounding area, so countermeasures are required if cleanliness is required.

(5) The shaft system from the motor M to the rotor of the dispersion chamber H (described later) is long, and there are mechanical connections at several points, so when using it at high speeds, the shaft system must be designed with strict vibration analysis. There is a need to.

(6) Since the motor M is an ordinary motor, that is, one with a fully enclosed external fan and a drip-proof structure, it is necessary to attach a stainless steel cover to the motor if it is used for food products that require sanitation.

(7) When processing high-temperature liquids or viscous liquids, in addition to two cooling systems: piping for cooling the dispersion chamber and cooling piping for the mechanical seal of the shaft seal, the motor cooling system when the motor is water-cooled is required. 3 cooling system, and the external piping becomes complicated.

Furthermore, a technique for integrating a motor and an agitator is generally disclosed in Japanese Utility Model Application Publication No. 51-60566.
However, in the case of an emulsifying disperser, a cooling system is required because it generates heat, and the technology of a stirrer cannot be applied. A canned motor type mixer is disclosed in Japanese Patent Application Laid-open No. 61-180826,
The motor is cooled by a single mixed liquid. However, in the case of an emulsifying and dispersing machine, since a high temperature liquid or a viscous liquid is used, the canned motor cannot be cooled, and it is not suitable for cleaning for sanitation purposes.

[Problems to be Solved] Therefore, an object of the present invention is to provide an emulsifying and dispersing machine that has a short axial length, is free from noise and vibration, and is capable of suitably cooling the drive motor and dispersion chamber.

[Means for Solving the Problems] According to the present invention, a dispersion chamber is arranged in the axial direction of the drive motor, a rotor of the dispersion machine is attached to the end of the output shaft of the drive motor extending into the dispersion chamber, and the casing of the dispersion machine In an in-line emulsification disperser equipped with a stator, the disperser casing is integrally attached to the drive motor housing, a mechanical seal is provided on the output shaft between the drive motor and the dispersion chamber, and an annular seal is installed around the outer periphery of the mechanical seal. A cooling chamber is formed, a casing cooling chamber is formed on the outer periphery of the disperser casing, a motor cooling chamber is formed on the outer periphery of the drive motor housing, and cooling water is supplied to the suction cover provided at the end of the disperser casing. A distribution pipe that communicates from the mouth with the motor cooling chamber, the casing cooling chamber, and the seal cooling chamber, and a confluence pipe that communicates with the motor cooling chamber, the casing cooling chamber, and the seal cooling chamber, and communicates with the cooling water outlet of the suction cover. It is equipped with

[Description of effects] Since the rotor is provided at the tip of the output shaft of the drive motor in this way, there is no need to provide couplings, bearings, speed increasers, etc. as in the conventional example, and the axial length can be reduced. It can be made shorter and saves installation space. Since cooling chambers are provided on the outer peripheries of the drive motor housing and the disperser casing, the problem of noise is eliminated.

Further, the drive motor housing, the disperser casing, and the mechanical seal can be cooled by the distribution pipe and the merging pipe, and the cooling system can be simplified, and at the same time, the external piping can also be simplified.

Since there is no coupling, it is easy to analyze the vibration of the output shaft, vibration can be reduced, and together with each cooling chamber, noise can be prevented, and an extremely quiet emulsifying and dispersing machine can be provided.

[Examples] Examples of the present invention will be described below with reference to the drawings.

In FIG. 1, a casing 10 of a dispersion chamber 12 is integrally attached to a motor housing 4 of a drive motor 1, and a rotor 8 of the dispersion chamber 12 is attached to an output shaft 7 of the motor 1, as will be described later. There is. Therefore, the coupling C of the conventional dispersing machine,
By eliminating the bearing B and the speed increaser G, the length in the axial direction can be shortened accordingly, and the installation space can be saved.

In FIG. 2, a variable-speed, high-speed drive motor, generally designated by the reference numeral 1, consists of a rotor 2, a stator 3, a motor housing 4, bearings 5, 6, and an output shaft 7. An annular motor cooling chamber A for cooling the coils of the stator 3 is defined between the motor cooling chamber A and the stator 3 .

A rotor 8 is fixed to the end of the output shaft 7,
A stator 9 is fixed to the disperser casing 10 opposite to the rotor 8. Between these rotor 8 and stator 9, there is a
As shown in No. 192174, a shear gap Cr is formed,
Different types of liquid raw materials M supplied from the suction port Ms of the suction cover 11 are sheared by the shear gap Cr, emulsified and dispersed, and are discharged from the raw material discharge port Md through the dispersion chamber 12. Therefore, the rotor 8 and stator 9 are provided with stepped portions Ts and Tr and tooth-shaped recesses 13 and 14 for efficient dispersion. An annular dispersion cooling chamber B is defined between the outer shell of the disperser casing 10 and the dispersion chamber 12 to suppress heat generation of the raw material caused by shearing.

Further, a mechanical seal 15 is provided in a portion of the output shaft 7 between the motor 1 and the dispersion chamber 12.
This prevents the raw material M in the dispersion chamber 12 from leaking to the motor 1 side. The mechanical seal 1
An annular seal cooling chamber C is defined on the outer periphery of the mechanical seal 5 to cool the sliding portion of the mechanical seal 15 that generates heat.

The distributor casing 10 is provided with a distribution pipe 16 that penetrates the cooling chamber B. One end of the distribution pipe 16 is connected to the cooling water supply port CW of the suction cover 11.
1, and the other end communicates with cooling chamber A through an orifice ORa, and communicates with cooling chamber C through a sufficiently large port 17 and an annular passage 16a surrounding distribution pipe 16. A plurality of (eight in the illustrated example) orifices ORb are provided in the portion of the distribution pipe 16 exposed to the cooling chamber B. This distribution pipe 16 has a cooling water supply port CW.
For example, tap water at a pressure of 1 to 3 Kgf/cm ² is supplied from the orifice ORb, flows out uniformly into the cooling chamber B, cools the disperser casing 10 surrounding the dispersion chamber 12, and cools the dispersion chamber 12. The internal pressure is controlled to 1 to 3 kg by an orifice ORc provided in the annular passage 18a surrounding the downstream merging pipe 18.
f/cm ² and an appropriate amount flows out.

The disperser casing 10 is provided with a merging pipe 18 symmetrically to the distribution pipe 16, which connects the cooling chambers A, B and C.
The cooling water returned from the suction cover 11 flows in through sufficiently large ports 19 and 20 and the orifice ORc, and is discharged from the cooling water outlet CW2 of the suction cover 11.

Therefore, since the distribution pipe 16 and the merging pipe 18 are provided in the disperser casing 10, the cooling pipes of the three systems (motor cooling system, dispersion chamber cooling system, mechanical seal cooling system) have one inlet and one outlet, respectively.
(CW1, CW2) is sufficient, and external piping is omitted. In addition, a water wall is formed between the cooling chambers A and B to block noise from the motor 1 and the dispersion chamber 12, making it possible to obtain a quiet dispersion machine. Additionally, the water volume in each system is adjusted by orifices ORa, ORb, and ORc, eliminating the need for flow rate adjustment valves. Furthermore, since the orifices ORa and ORb are located on the inlet side of the cooling chambers A and B, which have relatively large volumes, the pressure in the cooling chambers A and B becomes a low return pipe pressure, and the pressure in the cooling chambers A and B becomes low. The strength of B is reduced and the weight is reduced.

[Effects of the invention] As described above, the invention provides the following excellent effects.

() Since the rotor is directly connected to the output shaft of the drive motor, the axial length is short, saving installation space.

() Since there is a cooling chamber on the outer periphery of the drive motor housing and the disperser casing, noise from the motor and the dispersion chamber can be blocked, and a quiet disperser can be obtained.

() Cooling water can be supplied to the cooling chamber of the drive motor housing, disperser casing, and mechanical seal with one distribution pipe and one convergence pipe, simplifying the cooling system and simplifying external piping.

() Since there is no coupling on the output shaft, vibration analysis is easy and a vibration-free emulsification disperser can be obtained.

[Brief explanation of the drawing]

FIG. 1 is an overall configuration diagram showing an embodiment of the present invention;
FIG. 2 is a side sectional view, and FIGS. 3, 4, 5, and 6 are overall configuration diagrams showing different conventional disperser configurations. A, B, C... Cooling chamber, 1... Drive motor, 7
...Output shaft, 8...Rotor, 9...Stator, 1
0... Dispersion machine casing, 12... Dispersion chamber, 15
...Mechanil seal.

Claims (1)

[Scope of utility model registration request] In an in-line emulsifying and dispersing machine, the dispersion chamber is arranged in the axial direction of the drive motor, the rotor of the dispersion machine is attached to the end of the output shaft of the drive motor that extends into the dispersion chamber, and the stator is provided on the casing of the dispersion machine. The disperser casing is integrally attached to the motor housing, a mechanical seal is provided on the output shaft between the drive motor and the dispersion chamber, an annular seal cooling chamber is formed around the outer periphery of the mechanical seal, and an annular seal cooling chamber is formed around the outer periphery of the mechanical seal. A casing cooling chamber is formed, and a motor cooling chamber is formed on the outer periphery of the drive motor housing, and the cooling water supply port of the suction cover provided at the end of the disperser casing is connected to the motor cooling chamber, the casing cooling chamber, and the seal cooling chamber. An emulsifying and dispersing machine characterized by comprising: a distribution pipe communicating with the motor cooling chamber, the casing cooling chamber, and the seal cooling chamber, and a merging pipe communicating with the cooling water outlet of the suction cover.