KR102024878B1 - Sealing Device for Ratationg Shaft and Machine Appliance having the same - Google Patents

Abstract

The present invention includes a rotation shaft coupled to the casing rotatably in the receiving space of the casing having a receiving space receiving the rotational force of the drive unit rotated by a power source applied from the outside, the receiving space therein; And a material discharge guide unit coupled to the blade to guide the material flowing into the gap formed between the blade coupled to the rotating shaft and the casing to move away from the central axis of the rotating shaft as the rotating shaft rotates. do.
Therefore, according to the present invention, it is possible to prevent the received material to move to the rotation axis side to rotate, the raw material is coated on the area to be rotated to increase the frictional force and to prevent abrasion and wear parts can be replaced simply and conveniently It is possible to provide a rotating shaft sealing device and a mechanical device having the same.

Description

Sealing device for rotating shaft and machine device having same {Sealing Device for Ratationg Shaft and Machine Appliance having the same}

The present invention relates to a sealing device for a rotating shaft and a mechanical device having the same, and in particular, it is possible to prevent the fine material flowing into the rotating shaft in the process of performing a process including the mixing of the material contained therein to the rotary shaft The present invention relates to a rotating shaft sealing device and a mechanical device having the same, the structure of which is improved to be replaceable to abrasion part.

Various kinds of machines are used for industrial purposes, and among them, mixing machines are used to mix and accommodate the received materials.

That is, a plurality of raw materials may be added to a casing having a predetermined accommodation space in order to mix, mature, and process a plurality of raw materials at various composition ratios, and then the raw materials may be mixed while the casing or the rotating shaft rotates.

In the process such as blending, raw materials and the like may be introduced into the rotating shaft to damage the bearing, the grand packing, etc., which support the rotating shaft and the rotating shaft. Particularly, the finer and harder the powder is, the stronger the raw materials are.

Therefore, it is more effective to prevent the inflow of such fine or hard powder into the rotating shaft, and it is preferable to replace the part with particularly severe wear.

REFERENCES Publication No. 10-2008-0029789 (2008.04.03)

An object of the present invention is to provide a rotating shaft sealing device and a mechanical device having the same can prevent the movement of the received material toward the rotating shaft side, the raw material is coated in the area to be rotated to increase the friction force and prevent wear To provide.

Further, another object of the present invention is to provide a rotating shaft sealing device and a mechanical device having the same, which can be easily replaced with respect to abrasion part.

It is still another object of the present invention to provide a rotating shaft sealing device and a mechanical device having the same, in which raw materials move to the rotating shaft to reduce damage of bearings, gland packings, bushings, and the like.

Still another object of the present invention is to provide a rotating shaft sealing device and a mechanical device having the same, which can easily and conveniently have a structure that can prevent the received material from moving toward the rotating shaft side.

Still another object of the present invention is to provide a rotating shaft sealing device and a mechanical device having the same, which can reduce the repair and replacement period, and can improve durability, driving efficiency and economy.

An object of the present invention is a rotational shaft coupled to the casing rotatably coupled to the casing receiving the rotational force of the drive unit rotated by a power source applied from the outside, the housing space having a receiving space for receiving the material and the inside; ; And a material discharge guide unit coupled to the blade so that the material introduced into the gap formed between the blade coupled to the rotating shaft and the casing is moved away from the central axis of the rotating shaft as the rotating shaft rotates. Is achieved by a sealing device for a rotating shaft.

In addition, the material discharge induction portion is preferably disposed inclined so that the inner side is located in the front of the rotation direction and the outer side is located in the rear of the rotation direction so as to guide the material of the gap from the center axis to the outside in accordance with the rotation of the rotation axis. Do.

In addition, the material discharge induction part is disposed, wherein the material discharge induction part, the first discharge guide member provided over the entire length of the guide area, and the rear spaced apart in the rotational direction with the first discharge guide member A second discharge guide member provided over an intermediate region of the guide region, and a third discharge guide member provided over the outside of the guide region in an intermediate region of the guide region at a rearwardly spaced side from the second discharge guide member in a rotational direction; It is preferable to include.

In addition, the first discharge guide member, the second discharge guide member and the third discharge guide member is composed of a set is preferably a plurality of sets arranged in the induction region.

In addition, the rotation axis is disposed in the vertical direction, the material discharge guide portion is preferably coupled to the blade adjacent to the bottom surface of the casing.

In addition, it is preferable to include an airtight part including a labyrinth structure inside the material discharge induction part from the rotation axis center axis.

On the other hand, an object of the present invention, the drive unit to rotate by the power applied from the outside; A casing having an accommodating space for supporting a rotating shaft that is rotated by the rotational force of the driving unit and accommodating a material therein; The material flowing into the gap formed between the blade and the casing that is rotatably coupled to the rotating shaft in the receiving space of the casing is coupled to the blade so as to move away from the central axis of the rotating shaft as the rotating shaft rotates. It can also be achieved by a mechanical device having a rotating shaft sealing device comprising a; material discharge induction portion.

According to the present invention, there is provided a rotating shaft sealing device and a mechanical device having the same, which can prevent the received material from moving to the rotating shaft side, and which is coated with the raw material on the rotated area to prevent the friction force from increasing and abrasion. can do.

In addition, it is possible to provide a rotating shaft sealing device and a mechanical device having the same, which can be easily replaced with respect to abrasion part.

In addition, the raw material moves to the rotating shaft to reduce the damage of bearings, gland packing, bushing, etc., can increase the repair and replacement period, and improve the durability, driving efficiency and economy of the rotating shaft sealing device And a mechanical device having the same.

In addition, it is possible to provide a rotating shaft sealing device and a mechanical device having the same, which can easily and conveniently structure to prevent the received material from moving toward the rotating shaft side.

Figure 1a is a front view including the main sectional view of a rotating machine having a sealing device according to an embodiment of the present invention,
1B is a side view of FIG. 1A,
1c is a plan view of the sealing device,
1D is a longitudinal cross-sectional view of FIG. 1C;
1E is an enlarged cross-sectional view of the main portion of FIG. 1D;
FIG. 1F is a view of the main portion of FIG. 1C seen from below; FIG.
Figure 2a is an enlarged cross-sectional view including a wear member of another embodiment corresponding to the portion 1d,
2B is an enlarged cross-sectional view of a portion '2B' of FIG. 2A;
FIG. 2C is a bottom view taken along 2C-2C of FIG. 2A;
3a to 3e are related to the prior art for comparison with the present invention and corresponding to FIGS. 1a to 1e of the present invention.

A rotating shaft sealing device and a mixing machine having the same (hereinafter referred to as 'sealing device' 100 and 'mixing machine' 10) according to an embodiment of the present invention will be specifically described with reference to FIGS. 1A to 3E. Explained as follows.

Figure 1a is a front view including a main cross-sectional view of a rotating machine having a sealing device according to an embodiment of the present invention, Figure 1b is a side view of Figure 1a, Figure 1c is a plan view of the sealing device, Figure 1d of Figure 1c 1E is an enlarged cross-sectional view of the main part of FIG. 1D, FIG. 1F is a bottom view of the main part of FIG. 1C, and FIG. 2A is an enlarged cross-sectional view of a wear member of another embodiment corresponding to the portion of FIG. 1D, FIG. 2B is an enlarged cross-sectional view of a portion '2B' of FIG. 2A, FIG. 2C is a bottom view taken along 2C-2C of FIG. 2A, and FIGS. 3A to 3E are related to the related art for comparison with the present invention. 1A to 1E of the present invention.

The mixing machine 10 receives the rotational force of the driving unit 20 that is rotated by a power source applied from the outside, and has the accommodation space 31 of the casing 30 having an accommodation space 31 for accommodating a material therein. A rotating shaft 50 coupled to the casing 30 to be rotatable within; Center axis C of the rotary shaft 50 as the rotary shaft 50 rotates the material flowing into the gap (GAP) formed between the blade 110 and the casing 30 coupled to the rotary shaft 50 It is preferable to include a material discharge induction unit 130 coupled to the blade 110 to be guided away from.

The drive unit 20 includes a motor 21 that rotates by a power source applied from the outside, a reducer 23 that reduces the speed of the motor 21, and a rotation shaft 50 or a rotation shaft 50 so as to transmit power. And a coupling 25 for coupling the reducer 23 to each other, and a bearing 27 for rotatably supporting a rotating body such as the rotating shaft 50.

The casing 30 has a cylindrical shape that is long in the vertical direction, forcibly including iron, supported by an iron structure (not shown), etc., and forming an accommodating space 31 for accommodating a material therein, Rotating shaft 50 is rotatably coupled to the center, the inlet 33 is provided with the raw material is injected into the upper side, discharge outlet for discharging the raw material is completed in the receiving space 31, such as mixing process in the lower side ( 35).

Discharge port 35 is a place where the material that has completed the process, such as mixing is discharged in this embodiment is a kind of conveyor that can be transported to the place for the next process is not shown mixed material for the next process A discharge hole 35a guided by the transfer screw 40 and formed through the lower sidewall of the casing 30, a discharge gate 35b for slidingly opening and closing the discharge hole 35a, and a discharge hole 35a. It is provided with a discharge cylinder (35c) for moving the discharge gate (35b) to the open position to open the and the closed position to close the discharge hole (35a).

The rotating shaft 50 is defective in the casing 30 and the reducer 23 so as to be rotatable by the bearing 27, and is connected to each other by the coupling 25.

The rotating shaft 50 is a rod-shaped stirring member spaced radially (for example, different directions in a 90-degree direction of a constant height) at a predetermined angle in the vertical direction so that the raw materials in the accommodation space 31 can be mixed while rotating. 60 is coupled, and the material discharge induction unit 130 that forms a gap (GAP) and the bottom surface (not shown) of the casing 30 is coupled to the lower side of the receiving space (31).

The mill bone device 100 includes a blade 110 and a material discharge induction part 130.

The blade 110 has a cylindrical arm body 113 coupled to the rotating shaft 50 to rotate, and extends radially from the circumferential side of the arm body 113 to form a gap with the bottom surface of the casing. And a side farther away from the center axis C, which is closer to the inner side than the inner center axis C, to move the raw material contained in the accommodation space 31 to the outer side in the radial direction of the casing 30 in the rotational direction. Arm 115, which is inclined to be forward, and coupled to the outside of arm 115, functions like arm 115, and has a smaller and more slender shape to reduce the load more than arm 115. The scraper 117 is provided.

Here, the arm 115 and the scraper 117 is rotated while the rotational direction front side than the rear side so as to move the raw material located in the arm 115 and the scraper 117 to the upper side of the arm 115 and the scraper 117. It is preferable that it is sharply provided, and this structure can reduce the rotational frictional force of the rotation shaft 50 and more effectively mix it with the material, and can convey the material to the outlet 35 side.

On the other hand, the material discharge induction unit 130, as shown in Figure 1d to 1f, is provided in the gap (GAP) with the casing 30 which is the lower side of the arm body 113, the position close to the rotation axis 50 An airtight region Y having a conventional labyrinth structure has a constant width in a radial direction and a constant width in a radial direction outside the airtight region Y (M1 to M3 in FIG. 1E). Induction region X).

In the guide area X, the material discharge induction part 130 has an inner side in a rotational direction R so as to guide the material of the gap Gap outward from the central axis C according to the rotation of the rotation shaft 50. It is preferable to be inclined so as to be positioned in front of (see 'K1' and '133a' in FIG. 1F) and the outer side in the rear of the rotation direction R (see 'K2' and '133b' in FIG. 1F).

The material discharge induction part 130 may include a first discharge guide member 133 provided over the entire length of the guide area X, and a rear side spaced apart from the first discharge guide member 133 in the rotational direction R. The second discharge guide member 135 provided in the middle of the induction region (X) over the middle region, and the rear of the second discharge guide member 135 spaced apart in the rotational direction with the second discharge guide member 135 It is preferable to include a third discharge guide member 137 provided from the inner side of the outer end portion to the outer side of the induction region X. In addition, the first discharge guide member 133, the second discharge guide member 135 and the third discharge guide member 137 is composed of a set of the plurality of sets are arranged in the induction region (X). desirable. The first discharge guide member 133, the second discharge guide member 135 and the third discharge guide member 137 may be provided in various shapes, but in the present embodiment, for example, the height of the gap (GAP) 6.5mm For example, the width may include, for example, a rod shape having a rectangular cross section of 12 to 17 mm.

That is, the outside of the second discharge guide member 135 extends to a position farther in the radial direction than the center line of the induction region X (see 'M2' in FIGS. 1C and 1F), and the third discharge guide member 137. ) Is started at a position radially closer than the center line of the induction region X (see 'M2' in FIGS. 1C and 1F), so that the second discharge guide member 135 and the third discharge guide member 137 are formed. Is preferably overlapped at the center line (see 'M2') of the induction region X.

As described above, the rotary shaft 50 is disposed in the cylindrical casing 30 disposed vertically in the vertical direction, but the casing 30 is disposed in the horizontal direction of the left and right instead of vertically, so that the rotary shaft 50 is Of course, it can be applied even when disposed in the horizontal direction, in this case, it is preferable that the material discharge induction unit is coupled to the two blades adjacent to the left and right side walls of the casing.

Here, although the material discharge induction portion 130 has been described attached only to the lower side of the arm body 113, it may be formed on the lower side of the arm 115 and the scraper 117 as necessary. However, since the material is accumulated on the upper side of the arm 115 and the scraper 117, the self weight of the material is acting, and at the same time, the arm 115 and the scraper 117 push the material outward from the rotational center axis. Phenomenon such as sticking of the material between the gap between the scraper 117 and the bottom surface of the casing 30 can be prevented.

Corresponding to the mixing machine 10 according to the present invention, a mixing machine 200 according to the prior art is shown in FIGS. 3A-3E. For convenience of comparison, hereinafter, the last two digits of the reference number of the mixing machine 10 according to the prior art are applied in the same way as the last two digit reference numbers according to the present invention. The detailed description of the configuration will be omitted.

The mixing machine 200 of the prior art can be seen that there is no sealing device 100 according to the present invention as shown in Figs. 3c to 3e, but with a labyrinth structure corresponding to the airtight portion 139 of the present invention. It can be seen that only the airtight portion 139 is provided. Thus, in the prior art, the induction region X under the blade 110 is present in the gap GAP, so that the raw material including the fine powder is easily moved to the rotation shaft 50 through the labyrinth structure. There is a lot of wear and tear of the airtight device such as the gland packing device, the gap is coated with the raw material to increase the rotational frictional force and the wear of the blade is fast, so there is a lot of trouble to repair and replace frequently.

The mixing machine 10 according to the present invention, which improves the mixing machine 200 according to the related art, includes a first discharge guide member 133 and a second discharge guide, which are the material discharge guide units 130 provided in the guide area X. A plurality of members 135 and a third discharge guide member 137 are sequentially inclined along the rotational direction R, so that a raw material such as fine powder moved in the gap GAP is moved away in the radial direction of the rotation shaft 50. By providing a force that can be induced (see 'F133' 'F135' and 'F137' in FIG. 1F) to guide the fine raw material flowing between the gaps to the radially outer side of the rotation axis 50, It is possible to prevent the movement to the airtight portion 139 and the rotating shaft 50 or to minimize the amount of movement.

The mixing machine 10 according to the present invention can minimize the amount of fine powder that is moved to the rotating shaft 50, so that the replacement cycle of the grand packing of the rotating shaft 50 can be increased by about 50% compared to the conventional method. .

It goes without saying that the mixing machine 10 according to the present invention can be applied to, for example, a kneader for producing coal briquettes disclosed in Japanese Patent Laid-Open No. 10-2016-75260 (June 29, 2016).

Mixing machine 10 according to another embodiment according to the present invention, as shown in Figures 2a and 2b, having the above-described material discharge induction unit 130, while the material discharge induction portion 130 is a particularly wear-resistant part The blade wear member 150 is attached to the blade 110 detachably coupled to the blade 110 so as to be replaced when worn, and corresponds to the blade wear member 150. It characterized in that it has a plate-shaped casing wear member (170, see blue portion of Figure 2 and 2b) detachably coupled to the casing 30 in the opposite position.

Here, there is a gap (see 'GAP3' in Figure 2b) between the casing wear member 170 and the material discharge induction unit 130, and the gap between the rotating shaft 50 and the casing wear member 170 (' GAP4 'is preferably formed.

In addition, since the blade wear member 150 and the casing wear member 170 are severely worn, the surface treatment (for example, by cold spraying tungsten powder 0.3mm thick on the surface of the material SS400) Surface hardness of HRC 70 or more).

Here, the casing wear member 170 is included only in the region in which the labyrinth structure is formed, but may include a region up to the material discharge inducing unit 130 as necessary.

With this structure, the surface is treated for the longest use of the most abrasion parts and at the same time, it is easy and easy to replace the worn parts if there is a risk of serious damage to other parts of the machine. The effect can be obtained in the present invention.

On the other hand, reference numeral 180, which is not described, wear member fastening means including a bolt, washer that can firmly couple the blade wear member 150 and the casing wear member 170 to the blade 110 and the casing 30, respectively to be.

Accordingly, according to the present invention, a rotating shaft sealing device and a mechanical device having the same, which can prevent the received material from moving to the rotating shaft side, and prevent the wear of the raw material is coated on the rotated area to increase the frictional force and wear. Can be provided.

In addition, it is possible to provide a rotating shaft sealing device and a mechanical device having the same, which can be easily replaced with respect to abrasion part.

In addition, the raw material can move to the rotating shaft to reduce the damage of the bearing, gland packing, bushing, etc., reducing the repair and replacement period, and improve the durability, driving efficiency and economical sealing device for the rotating shaft And a mechanical device having the same.

In addition, it is possible to provide a rotating shaft sealing device and a mechanical device having the same, which can easily and conveniently structure to prevent the received material from moving toward the rotating shaft side.

Here, although an embodiment of the present invention has been illustrated and described, it will be appreciated by those skilled in the art that the present embodiment may be modified without departing from the spirit or spirit of the present invention. will be. It is intended that the scope of the invention be defined by the claims appended hereto and their equivalents.

10: mixing machine 20: drive unit
21; Motor 23: reducer
25 coupling 27 bearing
30: casing 31: accommodation space
33: inlet 35: outlet
35a: discharge hole 35b: discharge gate
35c: discharge cylinder 40: transfer screw
50: rotating shaft 60: stirring member
100: sealing device 110: blade
113: arm body 115: arm
117: scraper
130: material discharge induction part
133: first discharge guide member 135: second discharge guide member
137: third discharge guide member 139: airtight portion
150: blade wear member 170: casing wear member
180: wear member fastening means
GAP: clearance C: center axis
X: induction zone Y: hermetic zone
R: direction of rotation

Claims (7)

A rotating shaft coupled to the casing so as to receive a rotational force of the driving unit rotated by a power source applied from the outside, and to be rotatable in the accommodating space of the casing having an accommodating space accommodating the material therein;
And a material discharge guide unit coupled to the blade so that the material flowing into the gap formed between the blade coupled to the rotating shaft and the casing is moved away from the center axis of the rotating shaft as the rotating shaft rotates.
It includes a guide area in which the material discharge guide portion is disposed,
The material discharge induction part may include a first discharge provided over the entire length of the induction area.
An induction member, a second discharge induction member provided over the middle area of the induction area at a rearwardly spaced apart direction from the first discharge induction member, and the induction area at a rearwardly spaced distance from the second discharge induction member A third discharge guide member provided over the outside of the induction region in an intermediate region of the
A blade wear member detachably coupled to the blade to replace the material discharge induction part when worn;
And a casing wear member detachably coupled to the casing at a position corresponding to the blade wear member. The method of claim 1,
The material discharge induction part is disposed inclined so that the inner side is located in the front of the rotation direction and the outer side is located in the rear of the rotation direction so as to guide the material of the gap from the center axis to the outside in accordance with the rotation of the rotation axis. Shaft sealing device. delete delete delete delete delete

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