KR100805055B1 - An apparatus for preventing materials stored in a hopper from depositing and solidifying in the hopper - Google Patents

Abstract

An apparatus is provided for preventing the deposition and solidification of calcium chloride powder in a hopper in which calcium chloride powder which is continuously added to maintain the concentration of the plating solution during electroplating of steel sheet is stored.

The device 1 is installed to rotate in the longitudinal direction at the central portion of the hopper 10 in which the storage material 12 is stored therein, and a plurality of openings 32 and partitions 34 are integrally formed at the top and the inside. A cylindrical rotor (30) formed; and an opening / closing member (50) installed on the opening (32) side of the cylindrical rotor (30) to open and close it; and being installed to rotate on the rotor bulkhead (34). A crusher 72 for crushing the large coagulum 12 " introduced through the opening 32 and an induction pipe extending through the rotor 30 to the outlet 16 so as to discharge the coagulum crushed therefrom ( Crushing means (70) having a 74; and a solidification guide means (80) provided with a plurality of scraper knives (81) installed vertically and horizontally rotatable in a plural number rotatably around the central portion of the rotating body (30). );

Therefore, according to the present invention, since the storage material stored in the hopper solidifies with increasing humidity, and effectively prevents the storage material from being deposited under the hopper as its size increases, it is possible to control the concentration of the steel plate plating solution by the storage material. It is easy to prevent the plating failure of the electroplated steel sheet in advance.

Electroplating, galvanized steel, plating solution, hopper, hopper storage material, storage material solidification, storage material deposition

Description

AN APPARATUS FOR PREVENTING MATERIALS STORED IN A HOPPER FROM DEPOSITING AND SOLIDIFYING IN THE HOPPER}             

1 is a schematic diagram showing a state in which a storage material such as calcium chloride powder in a hopper is deposited or solidified

Figure 2 is a front configuration diagram showing the overall configuration of the storage material deposition and solidification prevention device in the hopper according to the present invention

3 is a cross-sectional view taken along the line A-A of FIG.

4 is a cross-sectional view taken along line B-B of FIG. 3 in the present inventors device;

5 is a cross-sectional view taken along the line C-C of FIG. 2 in the present inventors device;

6 is a cross-sectional view taken along the line D-D of FIG.

7 is a main structural diagram showing the guide means in the present inventors device;

Figure 8 is a perspective view of the main portion showing the guide means in the present inventors device

Figure 9 is a front view showing the main portion showing the rotation of the scraper knife of the guide means in the inventor device

Figure 10 is a perspective view of the main portion showing the scraper knife of the guiding means in the inventor device                 

Figure 11 is a perspective view of the main portion showing the opening and closing member in the inventor device

Figure 12 is a perspective view of the main portion showing a drive shaft for the operation of the opening and closing member in the inventor device

Explanation of symbols on the main parts of the drawings

1 .... Hopper Storage Solidification and Deposition Prevention

10 .... Hopper 12 .... Storage

14 .... screw 16 .... outlet

30 .... Rotator 32 .... Opening

34 .... bulkhead 36a, 52 .... drive motor

40,54 .... 1st, 2nd main shaft 50 .... Opening and closing member

56,58,84 .... Bevel Gears 57,59,82 .... Shafts

70 .... shredding means 72 ... shredders

74 .... exhaust duct 80 .... guide

81 .... scraper knife 86 .... drive shaft

88 .... working shaft 90 .... cover

92 .. Working arm 92a .... Connection box

93 .... housing 94 .... support shaft

96 .... Chain Pulley 98 .... Rack Moving Plate

99 .... Pinion gear A1, A2 ....

S .... Humidity Measurement Sensor

The present invention relates to a device for preventing the storage material such as calcium chloride powder from being deposited and solidified in the hopper in the hopper in which the calcium chloride powder continuously added to maintain the concentration of the plating solution during electroplating is stored. Inside the hopper, the coagulum of the storage material is introduced into the hopper and crushed, so that the storage material stored in the hopper solidifies as the humidity increases, and the size of the storage material gradually increases, and effectively prevents the deposit from the hopper. The present invention relates to a device for preventing the deposition and solidification of storage materials.

Generally, the solution used for zinc plating and zinc-nickel alloy plating of cold rolled products is about 75-85g / l zinc chloride (ZnCl ₂ ), about 260-290g / l calcium chloride (KCl), additives 0.4-0.6ml In addition, a plating solution containing nickel chloride (NiCl ₂ ) of about 8-12 g / l is used. Such a plating solution is used to meet the standard when the concentration of the solution is lower than the standard. The shortages should continue to be added. The zinc chloride, additives, nickel chloride, etc. are liquid, but calcium chloride is composed of powder, and the calcium chloride powder added to the plating solution is stored in the hopper, which is stored in the hopper. Calcium chloride powder is shown in FIG.

That is, as shown in FIG. 1, the calcium chloride powder 120 is charged and stored through the inlet 110 installed in the upper portion of the hopper 100, and the storage material 120 in the hopper 100 is an adjacently installed solution. As the water penetrates into the peripheral equipment such as a mixing tank for mixing the powder and the powder, the calcium chloride powder 120 in the hopper 100 solidifies, and the solidified material 120 'is gradually enlarged while being deposited under the hopper 100. Large coagulum 120 ".

Therefore, as shown in FIG. 1, the calcium chloride powder 120, which is a storage material, is somewhat small coagulum 120 ′ while passing through a screw 130 installed to drive the motor 132 at the outlet 102 under the hopper 100. ) Is discharged through the conveyor plate 140 below the outlet 102 while the coagulant 120 'is left for a long time, and the large coagulum 120' generated by being deposited under the hopper 100 is the screw. As 130, it is impossible to completely disintegrate and discharge.

As a result, in the hopper 100 in which a conventional storage material such as calcium chloride is stored therein, as shown in FIG. 1, the large coagulum 120 ″ blocks the outlet 102 of the hopper 100, thereby providing There was a problem that the plating line supply of the smooth calcium chloride 120 is not made through.

Accordingly, the plating solution is plated in a state in which the plating solution concentration is less than the standard value during electroplating of the steel sheet, which causes various plating defects such as uneven plating amount, stripping during plating, and plating peeling. In order to process the 120 "), a second additional work that requires the operator to enter the hopper 100 and remove the coagulum 120" by the washing operation is required, which in turn lowers the productivity of the entire plating line.

Accordingly, if the coagulum is crushed and discharged as a crusher installed under the duct while continuously inducing coagulum of a storage material such as calcium chloride powder stored in the hopper 100 into the duct in the hopper, the hopper storage material may be smoothly added to the mixing tank. It would be desirable to supply.

The present invention has been made in order to improve the various problems as described above, and its purpose is to guide the coagulant of the storage material in the hopper into the inlet duct and to crush it, so that the storage material stored in the hopper solidifies as the humidity increases In addition, the present invention is to provide a storage material deposition and solidification prevention device in the hopper that can be effectively prevented from being deposited to the lower hopper while gradually increasing in size.

On the other hand, another object of the present invention is to prevent the solidification and deposition of the storage material, such as calcium chloride powder stored in the hopper, supplying the plating line of calcium chloride powder is performed smoothly, according to the concentration control of the plating solution is easy An object of the present invention is to provide a storage material deposition and solidification prevention device in a hopper to prevent plating defects in advance.

The present invention as a technical configuration for achieving the above object, in the hopper for storing the storage material for plating the electrical steel plate is formed in which the storage material is stored therein and the storage outlet is provided with a screw in the lower portion, the central portion of the hopper It is installed so as to rotate in the longitudinal direction, the upper and the inner side of the cylindrical rotating body formed with a plurality of openings and partitions;

Opening and closing member which is installed to open and close it on the opening side of the cylindrical rotating body; And,

A crushing means having a crusher installed on the rotary partition wall to crush a large coagulum introduced through the opening and an induction pipe extending to the outlet through the rotator to discharge the coagulated crushed matter; And,

It is installed by a plurality of rotatable to the outer periphery of the rotating body, the solidification guide means having a plurality of scraper knives to operate vertically and horizontally; by providing a storage material deposition and solidification prevention device in the hopper consisting of.

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

Figure 2 is a front configuration diagram showing the overall configuration of the storage material deposition and solidification prevention device in the hopper according to the present invention, Figures 3 to 6 is a cross-sectional view of the line AA, BB, CC and DD of FIG. 7 and 8 are main parts showing the guide means of the device of the present invention, and Figs. 9 and 10 are main and front views and perspective views showing the scraper knife of the device guide means of the present invention, Figs. 11 and 12 Is an operating state diagram and a main part perspective view showing the opening and closing member of the present invention device.

Figure 2 shows the overall configuration of the storage material deposition and solidification prevention device in the hopper according to the present invention in a front configuration diagram, such a storage material deposition and solidification prevention device (1) in the hopper of the present invention largely It can be divided into the whole 30 and the opening and closing member 50 and the shredding means 70 and the guide means 80, each of the components 30, 50, 70, 80 will be described in detail as follows. .

First, Fig. 2 shows a hopper 10 related to the apparatus 1 of the present invention. The hopper 10 of the present invention has a calcium chloride powder supplied to a mixing tank so as to be introduced into a plating solution of an electrical steel sheet therein. The storage material 12 is stored, such as a screw for moving the storage material 12 by discharging the storage material 12, which normally does not have a coagulant in the lower portion of the hopper 10 to the conveyor plate 19 side ( 14 is installed, and the storage material outlet 16 is integrally formed at the bottom of the hopper 10 under the screw 14.

Next, FIGS. 2 and 3 to 6 show the rotor 30 of the device 1 of the present invention, which is the hopper 10 to serve as the base of the device. It is installed to rotate in the longitudinal direction at the central portion of the), a plurality of openings 32 and the partition wall 34 is formed integrally on the upper and inner sides.

That is, as shown in Figure 2, the drive shaft 36 and the coupling 38 of the first drive motor (36a) installed on the upper portion of the hopper 10 in the upper portion of the cylindrical rotating body 30 The first main shaft 40 is connected to the lower portion of the rotating body 30 is fixed to the connecting duct 18 of the lower side of the hopper 10 through the screw 14 of the hopper 10 Therefore, when the first drive motor 36a is driven, the rotating body 30 and the lower screw 14 are integrally rotated.                     

Meanwhile, as shown in FIG. 2, the first main shaft 40 includes an inner shaft 40a and an outer shaft 40b, and the inner shaft 40 of the rotating body 30 is provided through the screw 14. The outer shaft 40b is fixed to the bottom and the outer shaft 40b is separated from the inner shaft 40 through a bearing, and a power cable for driving the second driving motor 52 described below is inserted therein.

 And, as shown in Figure 2, the opening 32 formed in the rotating body 30 is integrally formed through four points at intervals of approximately 90 degrees in the circumferential direction of the rotating body 30, and the rotating body The partition 34 of the 30 is formed in a cylindrical shape with a lower portion narrow in the longitudinal direction of the rotating body 30 below the opening 32.

Next, FIG. 2 and FIG. 11 show the opening / closing member 50 of the apparatus 1 of the present invention, and this opening / closing member 50 is a case in which the rotating body of the large coagulum 12 " Open to pass through it, an arc shape is formed so as to be covered along the circumference of the opening and closing member 50, the rotating body 30 which is installed to open and close it on the opening 32 side of the cylindrical rotating body 30.

Meanwhile, as shown in FIGS. 2 and 11, a sealed first space A1 is provided below the partition wall 34 of the rotating body 30, and a second driving motor 52 is mounted, and the second driving motor 52 is mounted. A second main shaft 54 is connected to the drive motor 52 passing through the crusher 72 to be described later and extending into the second space A2 provided in the upper portion of the rotating body 30.

That is, as shown in Figs. 2, 6 and 11, the bevel gear 56 provided in the second main shaft 54 is horizontal and vertical to the rotating body second space A2 (Fig. 2). A plurality of bevel gears 58 fixed to the supported rotating shafts 57a and 57b are connected to each other, and an upper end portion of the opening and closing member 50 engages the bevel gear 58 of the rotating shaft 57b. A 58 is installed and connected to the rotating shaft 59 horizontally connected to the rotating body 30 through a connecting arm 50a so that the crusher 72 and the opening / closing member 50 when the second driving motor 52 is driven. It is configured to rotate.

Next, FIG. 2 shows the shredding means 70 of the apparatus 1 of the present invention. The shredding means 70 of the present invention is installed so as to rotate on the rotary bulkhead 34 so that the opening 32 A crusher 72 for crushing the large coagulum (12 ") introduced through the) and the induction pipe (74) extending to the outlet (16) side through the rotating body 30 to discharge the coagulum crushed through the Equipped.

On the other hand, as shown in Figure 3, the induction pipe 74 is connected to the upper end portion through the partition 34 of the rotating body 30, the lower end of the screw toward the outlet 16 side of the hopper 10 It extends in the form of being in close contact with the wall of the rotating body 30 up to 14, a total of about eight at intervals of about 45 degrees.

On the other hand, as shown in Figure 12, the second main shaft 54 is installed as a double shaft, the outer shaft 54b fixed to it while passing through the crusher 72 and the inner shaft 54a inserted into the inside thereof. And a gear portion 54d into which the gear 54c provided on the inner shaft 54a is inserted in the support ring 54e on the outer side, which is formed by the second drive motor of the inner shaft 54a. In the case of forward rotation, the outer shaft 54b is integrally driven as the gears are engaged, but in the case in which the second driving motor 52 is reversely rotated, the gears rotate around each other and the outer shaft 54b fixed to the crusher 72 is rotated. Does not reverse rotation, and eventually the crusher 72 connected to the outer shaft 54b is always rotated in one direction regardless of the rotation direction of the second main shaft 54.

Next, FIGS. 2 and 7 to 10 show the coagulation-inducing means 80 of the apparatus 1 of the present invention, and the coagulation material flow means 80 of the present invention is the rotary body 30. A plurality of pivotable knives 81 are installed rotatably around the center of the center and are operated vertically and horizontally.

In detail, the induction means 80 is connected to the second drive motor 52 and the chain 82a in the first space A1 and is 90 degrees to the outside of the space. A drive shaft 86 installed to rotate through the central portion of the rotating body 30 as the rotating shaft 82 and the bevel gears 84 vertically installed at intervals; An actuating shaft 88 installed with a bevel gear 88a engaged with the bevel gear 86a installed at the driving shaft 86 and connected to brackets 88b installed at both sides of the rotor 30; And a housing 93 fixed at the front of the connection box 92a installed at an end of the operation arm 92 passing through the cover 90 between the brackets with one end fixed to the operation shaft 88. In this case, the scraper knife 81 is connected to the housing 93 in the vertical and horizontal operation.

That is, as shown in Figs. 7 to 10, the scraper knife 81 is formed in a rhombus shape so that the rear end support shaft 94 is inserted and supported by the housing 93, the housing 93 A chain pulley 96 to which a plurality of chains 96a are connected is mounted on the support shaft 94 in the housing 93, and the housing 93 is formed in an arc shape.

In addition, one of the support shafts 94a selected from the support shafts 94 installed at the rear end of the scraper knife 81 is installed in the connection box 92a, and is horizontally fixed to the outside of the rotating body 30. The projection 97 on the fixed plate 97a is inserted into the lower guide hole 98a, and the pinion gear 99 is engaged with the rack moving plate 98 that moves up and down with the spring 98b elasticity. The scraper knife 81 is rotated in the vertical and horizontal directions according to the rotation of the 88. Since the calcium chloride, which is a storage material stored in the hopper 10, is in the form of powder, it is easy to move the hopper of the strapper knife 81. It is configured to act as a crushing of the small coagulum 12 'by rotating in the horizontal state while adjusting to make.

On the other hand, as shown in Figure 2, the hopper 10 is made of a configuration in which the humidity measuring sensor (S) is inserted into the storage material 12 through the hopper 10 in order to determine the formation of the coagulation. .

Referring to the operation of the present invention made in the above configuration in detail as follows.

As shown in Figures 2 to 12, when the storage material 10, such as calcium chloride powder is added to the plating solution of the electroplated steel sheet solidified with an increase in humidity in the hopper 10 by crushing it hopper 10 Storage material deposition and solidification prevention device (1) in the hopper of the present invention to more smoothly supply the storage material in the mixing tank is as follows.

First, as shown in FIG. 2, when the first drive motor 36a installed on the hopper 10 is operated, the rotating body 30 having the upper end integrally connected and fixed to the coupling 38 below is The rotating body 30, which is integrally rotated in the state supported by the connecting duct 18 below the hopper 10 by the lower first main shaft 40, is described in detail below as shown in FIG. The scraper knife 81 of the coagulated material guide means 80 which is horizontally deployed front, rear, left and right at the central portion of the rotating body is integrally rotated with the rotating body 30 in a horizontal state.

At this time, as shown in Figure 10, the scraper knife 81 is formed in a rhombus shape, the corner portion thereof is in the horizontal direction at this time, the scraper knife 81 is developed in an arc shape.

Therefore, when the first drive motor 36a is driven, the rotor 30 and the scraper knives 81 rotate in the hopper 10 and are connected to and fixed to the lower part of the rotor 30. Since the screw 14 on the outlet 16 side of the hopper 10 through which the shaft 40 passes also rotates integrally, the storage material in the hopper 10, that is, the calcium chloride powder 12, is connected to the connecting duct 18. It is supplied to the mixing tank as a conveyor plate 19 through.

At this time, the hopper 10 is installed on both sides of the humidity measuring sensor (S), if the humidity of the storage material 12 in the hopper 10 is greater than the reference value, the first drive motor (36a) Operation of the hopper 10 is stopped, and the second drive motor 52 disposed in the lower side of the hopper 10 is operated. Such a second drive motor 52 includes the opening and closing member 50 and the scraper knife described below. The coagulated material guide means (80) provided with (81) is pivoted up and down.                     

Therefore, when the operation of the initial first drive motor 36a is stopped, the operation of starting the second drive motor 52 for about 5 minutes and then operating the first drive motor 36a is repeated three times. When the scraper knives 81 of the guide means 80 are pivoted up three times, the large solidified product 12 ″ in the storage material 12 is opened by the opening / closing member 50. Flows into.

At this time, when a large coagulated product 12 "is introduced into the rotating body 30, it is led to the crusher 72 through the partition wall 34 installed to be sealed in the rotating body 30, and eventually the The crusher 72, through which the second main shaft 54 of the second drive motor 52 passes, crushes the large coagulum 12 " while rotating when the second drive motor 52 is driven, and finally the crushed solidification Water moves to the hopper outlet 16 side along the wall of the rotor 30 through a total of eight guide pipes 74 connected to the partition 34, and finally, by the operation of the first drive motor 36a as described above. It is discharged from the hopper.

That is, as shown in FIG. 2 and FIG. 6, when the operation is described in more detail, the first main shaft 40 is disposed in the first space A1 sealed as a partition wall formed inside the lower part of the rotating body 30. When the second drive motor 52 is operated as a power cable passing through the outer shaft 40b of the main body 40, the second main shaft 54 connected to the second drive motor 52 rotates the shredder 72. The bevel gear 56 installed at the upper end portion of the rotating shaft 57b which is continuously driven by driving the bevel gear 58 of one rotating shaft 57a horizontally and vertically supported in the second space A2 of the rotating body 30. The bevel gear 58 rotates the rotating shaft 59 horizontally connected to the rotating body 30 to rotate the opening and closing member 50 connected to the connecting arm 50a to the inner side of the rotating body 30 so as to rotate the rotating body 30. The openings 32 formed on the front, rear, left and right sides are opened on the upper side.

Next, as shown in FIGS. 2 and 7 and 8, the second driving motor 52 is driven to drive the second main shaft 54 and the second driving motor 52 and the chain 82a at the same time. ) Is connected to the rotating shaft 82,

Therefore, as shown in FIGS. 7 and 8, the driving force is transmitted to the rotating shaft 82 and the bevel gears 84 and the bevel gears installed on the driving shaft 86 penetrating the central portion of the rotating body 30 ( 86a rotates the bevel gear 88a of the actuating shaft 88 connected between the brackets 88b provided on the outer sides of the rotating body 30, and thus, one end is fixed to the actuating shaft 88 and rotated. The working arm 92 passing through the cover 90 fixed to the whole 30 is integrally rotated from a horizontal state to an almost vertical state.

Therefore, the arc-shaped housing 93 fixed forward of the connection box 92a fixed integrally to the distal end of the working arm 92 pivots upward, and the support shaft 94 of the rear end of the actuating arm 92 is pivoted upward. The insert-supported scraper knives 81 integrally move up toward the opening 32 of the rotor 30 to remove the intermediate or large coagulum 12 ″ generated in the reservoir 12. Induction charging into the opening allows the crushing and hopper discharge of the large coagulum 12 "

At this time, the scraper knife 81 can be rotated itself in a rhombus shape, which is in a horizontal direction during normal operation, and is vertically changed in the upward movement for the treatment of the coagulated product 12 ″ in calcium chloride. When the scraper knife 81 is initially in a horizontal state, the small coagulum 12 'is crushed in a collision while being rotated to facilitate the discharge by the lower screw.

That is, as shown in FIGS. 7, 9 and 10, when the scraper knives 81 are in a horizontal state, that is, their long edges are directed in the horizontal direction, the rack gear in the box 92a provided in the operating arm 92 is shown. The plate 98 is in the guide hole 98a in contact with the projection 97 on the fixed plate 97a horizontally fixed to the rotating body 30 inserted into the guide hole 98a under the box 92a.

However, as soon as the operation arm 92 is raised, the protrusion 97 is separated from the guide hole 98a, and eventually the rack gear plate 98 is moved downward by the elastic force of the upper and lower springs 98b. As a result, the pinion gear 99 on the support shaft 94a, which is engaged with the rack gear plate 98, rotates.

Therefore, as shown in FIGS. 9 and 10, when one of the support shafts 94a selected from among the support shafts is rotated, the one installed on the support shaft 94a and the other support shafts 94 is provided 96. Is connected to the chain (96a), the support shaft (94a) 94 is rotated about 90 degrees, eventually the long edges of the scraper knife 81 is shifted in the vertical direction in the horizontal direction guide means ( When the scraper knife 81 of 80 moves upward toward the opening / closing member 50, the large-size solidified product 12 "is guided into the rotating body 30 while easily moving in the storage material.

Meanwhile, as described above, the operation of the first driving motor 36a is stopped and the second driving motor 52 is continuously performed for about five minutes in the forward and reverse rotation operation, and then the second driving motor 52 is After the operation is stopped, the first drive motor 36a is operated for about 3 minutes, and the second drive motor 52 is rotated forward and backward while the operation of the first drive motor 36a is stopped again. If the operation is performed for about 5 minutes, the supply failure of the storage material 12 due to the coagulant of the hopper 10 may be prevented in advance, and the second driving motor 52 may be prevented. , The reverse rotation is for performing the operation of the scraper knife 81 and the opening and closing member 50 of the guide means 80 up and down 90 degrees and horizontal movement.

Accordingly, the storage material 12 in the hopper 10 is prevented from being deposited while solidifying, thereby effectively preventing hopper clogging caused by the large coagulum 12 ″.

As described above, according to the present invention, the storage material deposition and solidification prevention device in the hopper, by the solidification and deposition prevention of the storage material, such as calcium chloride powder stored in the hopper is performed, supplying the plating line of calcium chloride powder smoothly, accordingly the plating solution It is easy to manage the concentration of the steel plate to provide the effect of preventing plating defects in advance.

Therefore, it is possible to effectively prevent the plating peeling, stripping occurrence and uneven plating amount generated during the electroplating of the steel sheet due to the poor concentration of the plating solution to provide an excellent effect of improving the productivity of the overall electroplating line.

While the invention has been shown and described with respect to specific embodiments thereof, it will be apparent to those skilled in the art that various changes and modifications can be made without departing from the spirit or scope of the invention as set forth in the claims below. I would like to know that those who have knowledge of this can easily know.

Claims (5)

In the hopper 10 for storing the storage material for plating the electrical steel plate with the storage material 12 is stored therein and the storage material outlet 16 in which the screw 14 is installed at the bottom. It is installed to rotate in the longitudinal direction in the central portion of the hopper 10, the cylindrical rotor 30 formed integrally with a plurality of openings 32 and the partition 34 in the upper and inner; Opening and closing member 50 is installed to open and close it on the opening 32 side of the cylindrical rotating body 30; And, A crusher 72 installed to rotate on the rotor partition wall 34 to crush the large coagulum 12 " introduced through the opening 32; and a rotator 30 to discharge the crushed coagulum through the crusher 72; Shredding means (70) having a guide pipe (74) extending to the outlet port 16 side through; Storage inside the hopper consisting of; a plurality of rotatably installed to the outer periphery of the central portion of the rotating body 30, the solidification guide means 80 having a plurality of scraper knives 81 to operate vertically and horizontally Ash deposition and solidification prevention device  The cylindrical rotor 30 is coupled to the drive shaft 36 of the first drive motor 36a provided above the hopper 10, and coupled to the lower portion of the hopper 10. The first main shaft 40 is fixed to the connecting duct 18 under the hopper 10 through the screw 14 of the main body 40 is rotated when the motor 30 and the screw 14 are integrally rotated when the motor is driven. Is composed throughout,  The opening 32 formed in the rotating body 30 is integrally formed at four points at 90 degree intervals along the circumference, The partition wall 34 of the rotating body 30 is formed in a cylindrical shape of the lower portion in the longitudinal direction of the rotating body 30 to the lower side of the opening 32, the storage material deposition and solidification prevention device in the hopper. The method of claim 2, wherein the sealed first space (A1) is provided below the partition wall 34 of the rotating body 30, the second drive motor 52 is mounted, the second drive motor 52 is The second main shaft 54 which is passed through the crusher 72 and extended into the second space A2 provided on the upper portion of the rotating body 30 is connected, A plurality of bevel gears 58 fixed to the rotating shafts 57a and 57b horizontally and vertically supported in the rotating body second space A2 are connected to the bevel gear 56 installed on the second main shaft 54. Connected all the time, An upper end of the opening / closing member 50 is provided with a bevel gear 58 engaged with the bevel gear 58 of the rotation shaft 57b and connected to a rotation shaft 59 horizontally connected to the rotation body 30. Storage device deposition and solidification prevention device inside the hopper, characterized in that the crusher 72 and the opening and closing member 50 is configured to rotate when the second drive motor 52 is driven through The rotating shaft 82 of claim 1, wherein the induction means 80 is connected to the second drive motor 52 in the first space A1 and the chain 82a and vertically installed at an interval of 90 degrees to the outside of the space. Drive shafts (86) installed to rotate through the central portion of the rotating body (30) and bevel gears (84); An actuating shaft 88 installed with a bevel gear 88a engaged with the bevel gear 86a installed on the drive shaft 86 and connected to brackets 88b installed on both sides of the rotor 30; And, One end is fixed to the working shaft 88 and includes a housing 93 fixed to the front of the connection box (92a) is installed at the end of the operating arm 92 passing through the cover 90 between the bracket, The scraper knife 81 is the storage material deposition and solidification prevention device inside the hopper, characterized in that connected to the housing 93 in the vertical and horizontal operation 5. The scraper knife (81) according to claim 4, wherein the scraper knife (81) is formed in a rhombus shape so that the rear end support shaft (94) is inserted into and supported by the housing (93), and the support shaft (94) in the housing (93) A chain pulley 96 to which a plurality of chains 96a are connected is mounted, One of the support shafts 94a selected from the support shafts 94a is installed in the connection box 92a and has a protrusion 97 on a fixed plate 97a horizontally fixed to the outer side of the rotor 30. The pinion gear 99 is inserted into the guide hole 98a of the spring and engages with the rack moving plate 98 that is elastically moved up and down by the spring 98b. The scraper knife 81 is rotated according to the rotation of the operating shaft 88. ), Storage material deposition and solidification prevention device in the hopper, characterized in that configured to rotate in the vertical and horizontal directions

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