KR100884716B1 - Apparatus for transferring powder - Google Patents

Abstract

A powder transferring apparatus is provided to rotate a first transfer pipe using a rotating unit in order for powder to fall free, thereby reducing frictional resistance between the first transfer pipe and the powder and increasing speed of transferring the powder. A powder transferring apparatus(100) comprises the following units. A powder(1) is transferred to a first transfer pipe(110) through flowing air. Rotating units(210,220) increase speed of transferring the powder. A second transfer pipe is fixed on one side of the first transfer pipe. A third transfer pipe is fixed on other side of the first transfer pipe. The rotating unit rotates the first transfer pipe. Therefore, the powder transferred along the first transfer pipe falls free inside the first transfer pipe.

Description

Powder transfer device {Apparatus for transferring powder}

The present invention relates to a powder conveying apparatus, and more particularly, to a powder conveying apparatus for smoothly conveying powder without clogging.

In general, the powder conveying apparatus smoothly conveys various powders in a state such as flour, powdered milk or cement of foodstuffs or cutting dust generated in various industrial sites.

Referring to FIG. 1, in the conventional powder conveying apparatus, the compressor 20 is connected to one end of the conveying tube 10, and the powder (into the conveying tube 10) is connected to one side of the conveying tube 10. The hopper 30 for supplying 1) communicates with each other so that the compressed air of the compressor 20 is pressurized to the other end of the powder 1 in the transfer pipe 10.

Such a conventional powder conveying apparatus inevitably increases the air pressure of the compressor 20 at one end of the conveying tube 10 because the length of the conveying tube 10 is inevitably formed when conveying a large amount of powder at a long distance. Or increase the air volume. However, in this case, in the case of powder having a high viscosity or specific gravity even if the air pressure in the delivery pipe 10 is increased or the amount of air is increased, as shown in FIG. There is a problem that cannot be supported. Furthermore, in the case of powder having a high moisture content such as lime and coal tar, the water content of the powder increases during the transfer, and the viscosity of the powder may be very large. In this case, powder may accumulate in a pipe | tube, and the problem of blocking a pipe | tube may also arise.

It is an object of the present invention to provide a powder conveying apparatus which reduces the resistance in a tube to facilitate the conveyance of powder.

The present invention is a conveying pipe for conveying the powder by blowing; Rotating the conveying pipe, so that the powder conveyed into the conveying pipe continuously free fall, reducing the frictional resistance generated when the powder conveys the inside of the conveying pipe, while conveying the powder inside the conveying pipe It provides a powder conveying device comprising a rotating means to prevent the accumulation.

In this case, the transfer pipe may include a rotary joint to allow the transfer pipe to be rotatably coupled to the fixed tube when the end is coupled to the fixed tube not rotated by the rotation means. In addition, the transfer pipe may be rotatably coupled to the rotary joint in front of the curved portion of the stationary tube in which the feed speed of the powder is slowed.

In addition, even if the length of one side of the transfer tube is changed in length by expansion or compression depending on the temperature, the transfer tube is maintained in the state coupled to the rotary joint, the flexible to be rotated by the rotating means It may further include an auxiliary pipe having.

In addition, one side of the transfer pipe is provided with a longitudinal gear that is extrapolated, the rotating means, the rotating motor; It may be connected to the vertical gear in a state coupled to the rotary shaft of the rotary motor, when the rotary motor is operating, it may include a periodic gear for transmitting the rotational force to the vertical gear to rotate the feed pipe.

In addition, one side of the transfer pipe is provided with a longitudinal pulley that is extrapolated, the rotating means, the rotating motor; A main pulley coupled to the rotating shaft of the rotating motor; The main pulley and the bell pulley may be connected to each other, and when the rotary motor rotates, the rotational force may be transmitted to the bell pulley, and may include a connection belt for rotating the transfer pipe.

In addition, at least one is extrapolated to the transfer pipe to support the transfer pipe, and the inside of the transfer pipe may further include a rotation support provided with a ball bearing to rotate when the rotational force is transmitted by the rotation means.

In the powder conveying apparatus according to the present invention, the powder conveyed therein by the air flow falls freely while conveying the inside of the first conveyance pipe rotated by the rotating means. Therefore, the frictional resistance generated while the powder is transported inside the first transport pipe is reduced, and the speed at which the powder is transported inside the first transport pipe increases. In particular, the mar resistance is almost zero.

From this, the powder does not accumulate inside the first conveyance pipe, thereby enabling smooth conveyance of the powder.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 3 is a schematic sectional view of the powder conveying apparatus according to an embodiment of the present invention. Referring to FIG. 3, the powder conveying apparatus 100 includes a first conveying pipe 110 and rotating means 210 and 220. The first transport pipe 110 is a pipe for guiding the powder 1 to a position to be transported by flowing air.

One end of the first conveying pipe 110 generates air flow inside the first conveying pipe 110, and a blowing means (not shown) is connected to convey the powder 1, and the other end is Connect to the position where the powder (1) is introduced. However, the present invention is not limited thereto, and various methods may be considered at the level of those skilled in the art. That is, the powder 1 may flow by the pressure of the pressure tank (not shown). In addition, the blowing means may also be disposed in front of the first transfer pipe 110, may be disposed in the rear.

The powder conveying apparatus 100, the first conveying pipe 110 is provided with a second conveying pipe 300 and a rotary joint 400. One end of the second transfer pipe 300 communicates with the first transfer pipe 110, and the other end is fixed. The second transfer pipe 300 is disposed at the rear of the first transfer pipe 110 and has a curved pipe structure. The rotary joint 400 allows the first transfer pipe 110 to be coupled to the second transfer pipe 300 so as to be relatively rotatable.

Figure 4 is a schematic cross-sectional view of the powder conveying apparatus according to another embodiment of the present invention. Referring to FIG. 4, a second communication tube 310 connected to one side of the first transfer tube 120 and fixed to the other side of the first transfer tube 120 and fixed to the second transfer tube 310 may be fixed. Three conveying pipe 320 is included.

The powder conveying apparatus may include a first rotary joint 410 and a second rotary joint rotatably coupling the second conveying tube 310 and the third conveying tube 320 to the first conveying tube 120. 420 is further included. The first rotary joint 410 couples the first transfer pipe 120 to the second transfer pipe 310 so as to be relatively rotatable. In addition, the second rotary joint 420 couples the first transfer pipe 120 to the third transfer pipe 320 so as to be relatively rotatable.

The first transfer pipe 120 includes a first straight pipe portion 121, a second straight pipe portion 122, and a variable length portion 123. The first straight portion 121 is coupled to the first rotary joint 410, and the second straight portion 122 is coupled to the second rotary joint 420. The variable length part 123 connects the first straight pipe part 121 and the second straight pipe part 122. That is, the variable length part 123 has a corrugated pipe shape or has a ductility to absorb a length varying by thermal expansion or thermal contraction of the first straight pipe part 121 and the second straight pipe part 122. Therefore, the first conveying pipe 120 is rotated by the rotating means 210 and 220 enables stable rotation.

In addition, the first transport pipe (110, 120) is provided with a support (510, 520) for rotatably supporting the first transport pipe (110, 120). An embodiment of the support 510 is shown in FIG. 5. The support 510 includes a support tube 511 and a ball 514. The support tube 511 is formed with a through hole 512 such that the first transfer pipes 110 and 120 pass therethrough. The inner circumferential surface of the support tube 511 forms a plurality of grooves 513 so that the ball 514 to be described later is seated so as not to be separated outward.

The ball 514 is inserted into the groove 513 of the support tube 511 and disposed between the outer surface of the first transfer pipe 110 and 120 and the inner circumferential surface of the support tube 511. The ball 514 smoothly rotates in a state in which the first transport pipes 110 and 120 are supported by the support pipe 511.

Another embodiment of the support 520 is shown in FIG. 6. Referring to FIG. 6, the support 520 includes a rotation support 521 and a bearing 522. The rotation support 521 is extrapolated to the first transfer pipe 110, 120. In addition, the bearing 522 is inserted between the first transfer pipe 110 and 120 and the rotary support 521. Therefore, the bearing 522 smoothly rotates in a state in which the first transport pipes 110 and 120 are supported by the rotation support 521.

The rotating means 210, 220 generates a rotational force so that the first transfer pipe 110, 120 is rotated. Referring to FIG. 7, the rotating means 210 and 220 rotate the first conveying pipe 110 and 120 so that the powder 1 conveyed therein is the first conveying pipe 110 and 120. Free fall continuously within Therefore, the powder 1 is minimized to reach the surface of the transfer pipe 110, 120 when transported in the first transfer pipe 110, 120, the powder 1 and the first transfer pipe The frictional resistance between the (110) and (120) is reduced to increase the feed rate of the powder (1), so as not to accumulate inside the first transfer pipe (110) (120). At this time, the frictional resistance becomes almost zero.

An embodiment of the rotating means 210 is shown in FIG. 8. Referring to FIG. 8, in one embodiment of the rotating means 210, the rotary motor 211 includes a sprocket 212 and a chain 213.

The rotary motor 211 generates a rotational force to rotate the first transfer pipe (110, 120). The sprocket 212 is fixed to the first conveying pipe 110, 120, and transmits the rotational force transmitted by the chain 213 to the first conveying pipe 110, 120. The chain 213 is engaged with the sprocket 212, is connected to the rotary shaft of the rotary motor 211, and transmits the rotational force of the rotary motor 211 to the sprocket 212, the first The transfer pipe 110, 120 to rotate.

Therefore, when the rotational force generated by the rotating motor 211 of the rotating means 210 is transmitted to the sprocket 212 through the chain 213, the first transfer pipe 110, 120 is rotated. . As such, the powder 1 that is moved inside the first transport pipe 110 and 120 that is rotated is continuously dropped freely in the first transport pipe 110 and 120. Then, the frictional resistance generated when the powder 1 comes into contact with the surfaces of the first transfer pipes 110 and 120 becomes almost zero. Therefore, as the conveying speed of the powder 1 conveyed in the first conveying pipe 110 and 120 is increased, the powder 1 is not accumulated in the first conveying pipe 110 and 120. .

9 shows another embodiment of the rotating means 220. 9, in another embodiment of the rotating means 220, the rotary motor 221, the main pulley 222, a bell pulley 223, includes a connecting belt 224.

The rotary motor 220 generates a rotational force to rotate the first transfer pipe (110, 120). The main pulley 222 is coupled to the rotation axis of the rotary motor 221. The bell pulley 223 is fixed to the first transfer pipe 110 and 120, and transmits the rotational force transmitted by the connecting belt 224 to the first transfer pipe 110, 120. The connecting belt 224 is a belt connecting the main pulley 222 and the bell pulley 223. The connection belt 224 transmits the rotational force to the bellows 223 when the rotary motor 221 rotates, such that the first transfer pipe 110 and 120 rotate.

Therefore, when the rotational force generated by the rotating motor 221 of the rotating means 220 is transmitted to the bellows 223 through the main pulley 222 and the connecting belt 224, the first transfer pipe 110 and 120 are rotated. As such, the powder 1 that is moved inside the first transport pipe 110 and 120 that is rotated is continuously dropped freely in the first transport pipe 110 and 120. Then, the frictional resistance generated when the powder 1 comes into contact with the surfaces of the first transfer pipes 110 and 120 becomes almost zero. Therefore, as the conveying speed of the powder 1 conveyed in the first conveying pipe 110 and 120 is increased, the powder 1 is not accumulated in the first conveying pipe 110 and 120. .

As described above, the powder conveying apparatus 100 of the present invention includes the first conveying pipe 110 in which the powder 1 conveyed therein by air flow is rotated by the rotating means 210 and 220. 120) Allow free fall while conveying the inside. Accordingly, the powder 1 is substantially zero in frictional resistance generated while the powder 1 is transported inside the first transport pipe 110 and 120, so that the powder 1 is inside the first transport pipe 110 and 120. By increasing the speed of transport in, the powder (1) is not stacked in the first transfer pipe (110, 120) to enable a smooth transfer.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

1 is a schematic sectional view showing a conventional powder conveying apparatus.

2 is a transfer state diagram of the powder inside the transfer pipe of FIG. 1.

Figure 3 is a schematic sectional view of the powder conveying apparatus according to an embodiment of the present invention.

4 is a schematic sectional view of the powder conveying apparatus according to another embodiment of the present invention.

FIG. 5 is a cross-sectional view illustrating an installation of the support shown in FIG. 3. FIG.

6 is a cross-sectional view of an installation according to another embodiment of the support shown in FIG. 3.

7 is a state diagram of the powder when the first conveying tube shown in FIG. 3 rotates.

FIG. 8 is a cross-sectional view illustrating the configuration of the rotating means shown in FIG. 3.

FIG. 9 is a sectional view of a structure according to another embodiment of the rotating means shown in FIG. 3. FIG.

<Brief description of symbols for the main parts of the drawings>

1: powder 100: powder conveying apparatus

110, 120: first transport pipe 210, 220: rotation means

510, 520: support

Claims (10)

A first conveying pipe through which powder is conveyed by flowing air; Rotating the first feed pipe, freely dropping the powder transported in the first feed pipe in the first feed pipe, thereby reducing the frictional resistance between the powder and the first feed pipe, thereby reducing the powder Rotation means for increasing the feed rate of, A second transfer tube communicating with one side of the first transfer tube and fixed; A third transfer tube communicating with the other side of the first transfer tube and fixed; A first rotary joint to which the first transfer pipe is rotatably coupled to the second transfer pipe; And, The first transfer pipe further comprises a second rotary joint coupled to the third transfer pipe to be rotatable, The first transport pipe, A first straight pipe portion coupled to the first rotary joint; A second straight pipe portion coupled to the second rotary joint; A variable length part connecting the first straight pipe part and the second straight pipe part to absorb a length varying by thermal expansion or thermal contraction of the first straight pipe part and the second straight pipe part; Further comprising a support for rotatably supporting the first transfer pipe, The support, A support tube having a through hole formed therein so as to allow the first transfer pipe to pass therethrough; Is disposed between the outer surface of the first transfer pipe and the inner circumferential surface of the support tube, including a plurality of balls to facilitate the rotation of the first transfer tube with respect to the support tube, And a groove in which the plurality of balls are seated, formed on an inner circumferential surface of the support tube to prevent the plurality of balls from escaping to the outside. The method according to claim 1, The rotating means, A rotating motor; A sprocket fixed to the first conveying pipe; And And a chain engaged with the sprocket and transmitting a rotational force of the rotary motor to the sprocket to rotate the first transfer pipe. The method according to claim 1, The rotating means, A rotating motor; A main pulley coupled to the rotating shaft of the rotating motor; A bell pulley fixed to the first conveying pipe; Connecting the main pulley and the longitudinal pulley, transfer the rotational force of the rotary motor to the longitudinal pulley, the powder conveying apparatus comprising a connecting belt for rotating the first transfer pipe. delete delete delete delete delete delete delete

Images