KR101037706B1 - Planetary mixer - Google Patents

Abstract

The present invention provides a planetary mixer in which a tank is covered with a hood, and the inside thereof is heated, pressurized, and vacuum-reduced, or treated, and there is no risk that the lubricant contained in the rotor will leak when the tank is opened to atmospheric pressure. It is a subject to offer.

To this end, the rotor 9 is rotatably attached to the lower portion of the support cylinder 13 fixed to the stirring head 3. The support passage 13 is formed with an air passage 21 for communicating the inside and the outside of the rotor 9. The pressure release valve 28 which communicates with air | atmosphere is provided in the outer opening end 23 of this air passage 21.

Planetary mixer

Description

Planetary Mixer {PLANETARY MIXER}

The present invention relates to a planetary mixer in which a blade is planetary in a tank to knead the treating material.

Background Art Conventionally, planetary mixers are known in which planetary motion of a plurality of blades in a tank is carried out as a kneading disperser for dispersing, stirring, or kneading high viscosity (~ 3000 Pa.s) or semi-solid processing materials from low viscosity (e.g., See Patent Document 1). In general, the planetary mixer is provided with a drive shaft in a lifting and lowering stirring head, and attaches a rotor containing a driving member such as a gear for planetary movement of the blade shaft below, and lowers the stirring head to the lower end of the blade shaft. The attached blade is inserted into the tank, and the rotor is rotated by the drive shaft to make the blade planetary motion. At this time, a planetary mixer having a hood installed around the rotor to cover the upper surface of the tank and seal the inside of the tank is also widely used. When the hood is used, the inside of the tank can be heated, pressurized, or vacuum depressurized. The kneading | mixing etc. can be performed as a state. In the rotor, lubricating oil of a driving member is sealed, and shaft seal members such as an oil seal are provided in the shaft through portion of the rotor mounted on the driving shaft so that the lubricating oil does not leak. By this shaft sealing member, for example, when operating under atmospheric pressure without using a hood, lubricating oil can be prevented from leaking.

However, as mentioned above, when a tank is covered with a hood and heated, pressurized, and vacuum-reduced in a sealed state, the lubricant may be leaked. In detail, the shaft (or sleeve) portion sliding to the shaft seal member is formed so as to minimize the irregularities as much as possible by preventing the leakage of the lubricating oil by strictly defining and managing the surface roughness. The pressure in the tank and the hood is increased by increasing the temperature of the material, pressurizing with nitrogen gas, or the like, and pressure is gradually applied to the inside of the rotor through a slight wear portion occurring in the shaft sliding portion of the shaft seal member. In this way, since the pressure in the rotor is at the same pressure as in the tank at the time of operation, no lubricant leakage occurs. However, if the hood is removed after the end of the operation, the inside of the tank is opened to atmospheric pressure, but the inside of the rotor does not immediately become atmospheric pressure even if the tank is brought to atmospheric pressure. That is, since the shaft through portion is sealed by the shaft seal member, the inside of the rotor still maintains pressure. In addition, when a sudden pressure difference occurs inside and outside the rotor, when the residual pressure inside the rotor gradually falls, a phenomenon in which lubricant is leaked is observed. In the case of pressurizing the inside of the tank and vacuum depressurizing, the mounting direction of the shaft seal member of the rotor is completely reversed. For example, assuming that the shaft seal member is provided assuming that the tank is pressurized. When the inside of a tank was vacuum-reduced or processed, the lubricating oil leaked in some cases. In this way, when lubricating oil leaks, lubricating oil is mixed in the product, so careful attention is required in operation and operation. If lubricating oil leakage occurs, economical loss is a problem when processing expensive products.

[Patent Document 1] Japanese Utility Model Publication Hei 5-5-66

The problem to be solved by the present invention is a planetary mixer in which a tank is covered with a hood, and the inside thereof is heated, pressurized, vacuum-reduced, or treated, where the tank and the hood are opened to atmospheric pressure after the treatment. It is to provide a planetary mixer in which the pressure difference between the inside of the hood (outside of the rotor) and the inside of the rotor is eliminated so that the lubricant enclosed in the rotor is not leaked.

According to the present invention, a rotor including a drive member for planetary movement of a blade shaft under a stirring head, and a planetary mixer provided with a hood so as to cover a tank around the rotor, the rotor provided with the drive member The planetary mixer is provided by forming an air passage communicating the inside and the outside of the air passage, and communicating the open end of the air passage to an openable pressure releasing valve communicating with the atmosphere.

(Effects of the Invention)

The present invention is constructed as described above, the tank is formed by communicating the inside and the outside of the rotor provided with the drive member, and the open end of the passage is in communication with an openable pressure release valve for communicating with the atmosphere tank When the inside is heated, pressurized, vacuum-reduced or treated, and then opened to atmospheric pressure, the pressure discharge valve is opened at the same time, so that the internal pressure of the rotor can be the same as the atmospheric pressure. Therefore, since a pressure difference does not occur between the inside and the outside of the rotor, and a pressure balance without a pressure difference occurs, leakage of lubricant from the rotor can be effectively prevented, and there is no fear that the lubricant will be incorporated into the product.

The present invention can be applied to various planetary mixers, and as shown in FIG. 1, the planetary mixer main body 1 has a stirring head 3 which is lifted and lowered by a lifting cylinder 2. When (3) descends, the blade 5 is provided so that it may be inserted in the tank 4. The stirring head 3 is provided with a drive shaft 8 (FIG. 2) rotated by a motor 6, a reducer 7, and the like, and a rotor 9 is connected to a lower end of the drive shaft 8, and the rotor The blade 5 is attached to 9. A lower surface of the stirring head 3 surrounds the rotor 9 and a hood 10 is formed, and the hood 10 may cover the upper surface of the tank 4 as is known.

The rotor 9 has a gear box 11 accommodating a drive member for planetary movement of the blade 5 and a bearing shaft bearing box 12 for hermetically connected below. As shown in FIG. 2, the gear box 11 is rotatably connected to a lower portion of a support cylinder (bearing case) 13 fixed to the stirring head 3, and within the support cylinder 13. The drive shaft 8 is inserted, and the lower end of the drive shaft 8 is fixed to the bearing box 12 for the blade shaft. Between the outer circumferential surface of the drive shaft 8 and the inner circumferential surface of the support cylinder 13 and between the outer circumferential surface of the support cylinder 13 and the inner circumferential surface of the gear box 11 are shaft seal members 14 such as bearings and oil seals, respectively. Is provided so that the lubricating oil (not shown) enclosed in the gear box 11 does not leak.

The blade shaft 15 is axially supported by the bearing 16 in the blade shaft bearing box 12. A planetary gear 17 is fixed to an upper end of the blade shaft 15 as a drive member for driving the blade shaft 15, and the planetary gear 17 is a sun gear provided at a lower end of the support cylinder 13. (18) is interlocked. In the illustration, the sun gear is located inside the planetary gear, but the inner tooth sun gear may be used so as to be located outside the planetary gear.

The support cylinder 13 has a flange 19 at its middle portion, and the flange 19 is fixed in contact with the attachment cylinder 20 installed at the lower part of the stirring head 3, and the upper end thereof. Is projected upward from the attachment cylinder 20. A vent passage 21 extending in the longitudinal direction in the drawing is formed in the cylinder portion of the support cylinder 13, and the vent passage 21 is an inner opening end 22 that opens in the gear box 11. And the outer opening end 23 opened upward of the attachment cylinder 20. By this structure, the inside of the gear box 11 is in communication with the outside of the hood 10. In addition, an air pipe 24 is connected to the outer opening end 23 of the air passage 21, and the air pipe 24 is connected to the air through a flow control valve 25 such as a needle valve. The pressure discharge valve 28 which can selectively communicate with the communication pipe 26 and the compressed air pipe 27 which communicates with a compressed air source (not shown) is provided. In addition, a pressure relief valve may be directly attached to the outer opening end without providing the air pipe.

When the pressure discharge valve 28 is closed, the air passage 21 is sealed, and when opened, the air passage 21 communicates with the atmosphere. When lubricating oil or the like is blocked in the air passage 21, the air communication tube 26 is closed by communicating with the air communication tube 26 so that compressed air is introduced into the air passage 21 so that air is introduced into the air passage 21. Blowing, washing | cleaning, etc. can be performed easily. In addition, by controlling the amount of air flowing in the air pipe 24 by operating the flow control valve 25, the time for returning the inside of the gear box 11 to atmospheric pressure can be adjusted, or the strength of air blow or cleaning can be added or decreased. have.

Preferably, a plurality of the air passages may be formed. For example, as shown in FIG. 3, four air passages may be formed, but considering the strength of the support cylinder, a suitable number of about 2 to 4 Can be. The pressure relief valve may be attached to each air passage, but when a plurality of air passages are formed, for example, as shown in FIG. 4, the air pipe connecting the plurality of tubes 29 by the joint member 30 ( 24, a flow rate regulating valve 25 or a pressure relief valve 28 are provided in the air pipe 24, and at the tip of the tube 29, the outside of each air passage 21 is opened. What is necessary is just to provide the connection part 31 which can be connected to the ball | bowl 23. In addition, in the said embodiment, when the outer opening end 23 of the said ventilation path 21 opens in the upper direction of the said attachment cylinder 20, if it is the structure which communicates with the exterior of the said rotor 9, the hood 10 will be carried out. It may be open in the inside, and can be installed in other suitable positions.

With the above structure, the tank 4 is covered by the hood 10, and the inside thereof is heated, pressurized, and vacuum-reduced or operated in a state where the inside of the tank 4 is raised by raising the stirring head 3. When opening to atmospheric pressure, simultaneously operating the pressure release valve 28 to communicate the air passage 21 to the atmosphere, the inside of the rotor 9 through the air passage 21 is also equal to the atmospheric pressure. Therefore, since no pressure difference occurs inside and outside the rotor 9, lubricating oil leakage is effectively prevented.

1 is a schematic diagram showing an embodiment of the present invention.

It is explanatory drawing which expanded a part of rotor part of the embodiment shown in FIG.

3 shows another embodiment of the present invention, (A) is a half sectional view of the support cylinder, and (B) is a sectional view of the outer opening end portion.

4 is an explanatory diagram showing an embodiment of an air pipe.

(Explanation of symbols for the main parts of the drawing)

1: body 3: stirring head

4: tank 5: blade

8: drive shaft 9: rotor

10: hood 11: gearbox

12: bearing box 13: support cylinder

14: shaft seal member 20: attachment cylinder

21: Aeration 22: Inner opening end

23: Outer opening end 24: Air piping

25: flow control valve 26: atmospheric communication pipe

27: compressed air pipe 28: pressure relief valve

Claims (5)

In a planetary mixer having a rotor accommodating a drive member for planetary movement of a blade shaft below a stirring head, and having a hood provided to cover a tank around the rotor: And a vent passage communicating with the inside and the outside of the rotor provided with the drive member, and communicating with an open / close pressure release valve passing through the opening end of the vent passage into the atmosphere. The said rotor is rotatably supported by the lower part of the support cylinder attached to the said stirring head, The drive shaft which drives the said drive member is inserted in the said support cylinder, The shaft is between the said drive shaft and the rotor. And a sealing member is provided, wherein the air passage is formed in the support cylinder, one end of the air passage is opened in the rotor, and the other end is opened to the outside of the hood. The planetary mixer according to claim 1 or 2, wherein a plurality of the air passages are formed. The planetary mixer according to claim 3, wherein the open ends of the plurality of air passages are connected to an air pipe having the pressure discharge valve, and the air pipe is selectively communicated with a compressed air source and the atmosphere. . The planetary mixer according to claim 4, wherein the air pipe is provided with a flow control valve.

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