JP6589188B1 - Quick flux equipment - Google Patents

Abstract

The present invention discloses a quick flux facility. A first empty cavity that includes an apparatus main body and that opens upward is installed in the apparatus main body, and a first transmission cavity located on the right side of the first empty cavity is provided in the apparatus main body. A first rotating shaft extending from side to side is rotatably fitted between the first transmission cavity and the first empty cavity, and the left end of the first rotating shaft rotates. A first crushing wheel that is engaged with and connected to the left end wall of the first empty cavity and fixedly mounted on the outer surface of the first rotating shaft is installed in the first empty cavity; A first spur gear fixedly mounted on the right end of the first rotating shaft is installed in the transmission cavity, and is located between the first empty cavity and the first transmission cavity in the apparatus body. A second transmission cavity is installed. [Selection] Figure 1

Description

The present invention relates to the technical field of processing a flux, and more particularly to a quick flux facility.

Flux refers to a third type of substance that reduces the tension at the brazing filler metal interface. In welding, by producing slag and fuselage, it acts to protect the melting metal, it is necessary to dry with reference to the instructions for use, and the granularity of the flux is required, Both the size of the granule and the dry quality can greatly affect the use of the flux, and traditional flux processing equipment generally performs separate drying and polishing crafts, reducing the preparation efficiency of workers and improving the quality of drying. Will also have an effect.

Chinese Patent Application No. 102513737 Specification

The object of the present invention is to provide a quick flux facility to compensate for the above drawbacks in the existing technology.

The quick flux equipment of the present invention includes an apparatus main body, a first empty cavity opened upward is installed in the apparatus main body, and a first empty cavity located on the right side of the first empty cavity is installed in the apparatus main body. A transmission cavity is installed, and a first rotary shaft extending in the left and right direction is rotatably engaged and mounted between the first transmission cavity and the first empty cavity, and the first rotary shaft A first crushing wheel that is engaged with and connected to the left end wall of the first empty cavity so that the left end of the first empty cavity can rotate, and that is fixedly attached to the outer surface of the first rotating shaft is installed in the first empty cavity. The first transmission cavity is provided with a first spur gear fixedly attached to the right end of the first rotating shaft, and the apparatus main body includes the first empty cavity and the first transmission cavity. Second transmission gear located between A tee is installed, and the first rotating shaft passes through the second transmission cavity so as to rotate, and the second transmission cavity is fixedly mounted on the outer surface of the first rotating shaft. A gear is installed, and a second rotary shaft extending from side to side is engaged and mounted between the second transmission cavity and the first empty cavity so that the second rotary shaft can rotate. It is located on the rear side of one rotation shaft, and is engaged and connected so that the left end of the second rotation shaft can rotate with the left end wall of the first empty cavity. A third spur gear fixedly mounted on the outer surface of the second spur gear and the third spur gear meshes with the second spur gear, and the first empty cavity has an outer surface of the second rotating shaft. A second crushing wheel that is fixedly mounted and engages with the first crushing wheel is installed. A third transmission cavity located on the right side of the first transmission cavity is installed in the apparatus main body, and the third transmission cavity extends to the left and right between the third transmission cavity and the first transmission cavity. An irregular spur gear fixedly mounted on the left end of the third rotating shaft is installed in the first transmission cavity so that the three rotating shafts can rotate, and the irregular spur gear is connected to the first spur gear. A first bevel gear fixed to the right end of the third rotating shaft is installed in the third transmission cavity, and the device main body has a lower part of the third transmission cavity. A fourth transmission cavity located on the third transmission cavity, and a fourth rotary shaft extending vertically is engaged and mounted between the third transmission cavity and the fourth transmission cavity so as to rotate. Transmission cabinet A rotation motor is fixedly mounted in the upper end wall of the tee, the lower end of the rotation motor and the fourth rotation shaft are connected , and the lower end of the fourth rotation shaft can rotate with the lower end wall of the fourth transmission cavity. In the third transmission cavity, a second bevel gear located on the outer surface of the fourth rotating shaft and meshing with the first bevel gear is fixedly mounted in the device main body. Has a second empty cavity located below the first empty cavity, and a right end wall of the second empty cavity communicates with the fourth transmission cavity, and the first empty cavity and the second empty cavity are in communication with each other. a third air cavity is installed in communication between the cavity and into the second air cavity is installed transmission mounting block fixed mounted in the second air cavity by a connecting bracket, the transmission Mounting bracket Tsu is the upper end of the click is engageable mounted so that it can rotate cylindrical rotating block, said the upper end of the cylindrical rotary block is installed tapered inclined surface, wherein the inner wall above the second air cavity cyclic rotation block The upper end surface of the annular rotary block is provided with an inclined surface extending to the cylindrical rotary block, and an annular groove communicates with the inner wall of the second empty cavity. An outer gear that is fixedly mounted on the outer surface of the annular rotary block is installed in the annular groove, and the device main body is provided between the third transmission cavity and the fourth transmission cavity. A fifth transmission cavity is located, and the fourth rotation shaft passes through the fifth transmission cavity so as to rotate, and the fifth transmission cavity has an outer surface of the fourth rotation shaft. First transmission gear is disposed to be fixedly attached to the right end wall of the annular groove is disposed in communication with the sixth transmission cavity and said sixth transmission cavity is positioned below the fifth transmission cavity, A fifth rotation shaft is engaged and connected between the sixth transmission cavity and the fifth transmission cavity, and is fixedly mounted on the upper end of the fifth rotation shaft in the fifth transmission cavity. A second transmission wheel is installed, and a first transmission belt is connected between the first transmission wheel and the second transmission wheel so that the first transmission belt can be transmitted, and the fifth rotation shaft is disposed in the sixth transmission cavity. A fourth spur gear fixedly attached to the lower end of the cylindrical rotating block and meshing with the outer ring gear is installed; crushing blocks are respectively installed on the outer circumferential surface of the cylindrical rotating block and the inner circumferential surface of the annular rotating block; and Cylindrical rotating block The positions of the crushing blocks on the outer circumferential surface of the lock and the crushing blocks on the inner circumferential surface of the annular rotating block are shifted up and down, and the outer surface of the cylindrical rotating block is in the second empty cavity. A filtration device fixedly mounted on the lower side is installed, one end of the filtration device that is far from the cylindrical rotary block abuts on the annular rotary block, and an open groove that opens upward in the transmission mounting block Is installed in the lower end wall of the open groove so that a sixth rotary shaft extending upward can rotate, and the sixth rotary shaft is inserted into the cylindrical rotary block. The cylindrical rotary block is fixedly engaged and connected, and a communication groove communicating with the second empty cavity is installed in the right end wall of the open groove, and the open groove includes the sixth rotary shaft. No. fixedly attached to the outer surface A transmission wheel is installed, and in the fourth transmission cavity, a fourth transmission wheel fixedly mounted on the outer surface of the fourth rotating shaft is installed, and between the third transmission wheel and the fourth transmission wheel. Is connected to be able to transmit a second transmission belt, and an outlet opening downwardly located below the second empty cavity is installed in the apparatus body, and the outlet and the second empty cavity A fourth empty cavity is communicated between the two.

As a further technical plan, an inlet mounting block located above the first empty cavity is fixedly attached to the upper end of the apparatus main body, and the inlet mounting block penetrates up and down in communication with the first empty cavity. A flux inlet is provided, and a slope extending in the direction of the first empty cavity is provided at the flux inlet, thereby providing convenience for adding a flux raw material, and the flux inlet includes the first empty cavity. Slopes extending in the direction are installed, which provides convenience for adding flux raw materials.

As a further technical plan, a heating resistance wire is fixedly attached to the opposite end faces of the annular rotary block and the cylindrical rotary block, and the heating resistance wire is dried against the flux in the second empty cavity. Carry out driving.

As a further technical plan, a symmetrical mounting base is fixedly attached to the lower end wall of the apparatus main body, a support base is fixedly attached to the lower end of the mounting base, and the stability of the support base when the apparatus is operated is improved. To increase.

The beneficial effects of the present invention are: When in use, an operator adds the flux raw material into the first empty cavity via the flux inlet, at which time the rotary motor is activated and the rotary motor is connected through the fourth rotary shaft. The second bevel gear is rotated by moving the second bevel gear, and the second bevel gear is rotated by moving the third rotation shaft according to the meshing relationship between the first bevel gear and the third rotation shaft is rotated between the irregular spur gear and the first spur gear. The first rotating shaft is moved and rotated by the meshing relationship between the first rotating shaft and the first crushing wheel is moved and rotated. At the same time, the first rotating shaft is meshed between the second spur gear and the third spur gear. Depending on the relationship, the second crushing wheel was moved and rotated, and at this time, the first crushing wheel and the second crushing wheel performed initial polishing on the flux raw material in the first empty cavity, and the initial polishing was performed. Flux raw material passes through the third empty cavity to the second empty cavity At this time, the fourth rotating shaft moves and rotates the fifth rotating shaft through the engagement of power between the first transmission wheel and the second transmitting wheel, and the fifth rotating shaft rotates with the fourth spur gear. The annular rotary block is moved and rotated through the meshing relationship with the outer gear, and at the same time, the fourth rotary shaft is rotated by moving the sixth rotary shaft through the engagement of power between the fourth and third transmission wheels. The sixth rotating shaft moves and rotates the cylindrical rotating block, and the rotating direction of the cylindrical rotating block is opposite to the annular rotating block. At this time, the outer surface of the cylindrical rotating block and the annular rotating block is The flux material is finally polished by the crushing block, and at the same time, the heating resistance wire is activated to dry the flux in the second empty cavity, and the processed flux at this time is separated into the filtration device and the fourth empty cavity. Via It is discharged from the outlet.

The present invention is simple in structure, easy to operate, and completes each step from flux polishing to drying, etc. by a closely assembled transmission structure, thereby providing convenient use of the flux, and by secondary polishing on the flux The final granularity of the final flux product is made finer, the polishing and drying crafts for flux are advanced simultaneously, the flux processing efficiency is increased, and the flux material is made more convenient through the slope installed at the entrance. In addition, the support platform enhances the stability during operation of the device, thereby increasing the effect of using the flux.

FIG. 1 is a schematic diagram of the entire internal structure of a quick flux facility according to the present invention. FIG. 2 is a schematic cross-sectional view taken along the line AA in FIG. 1 of the present invention. FIG. 3 is a schematic view of meshing of the irregular gear in FIG. 1 of the present invention. FIG. 4 is a structural schematic diagram of B in FIG. 1 of the present invention.

The present invention will be described in detail with reference to FIGS. For convenience of explanation, the following orientations are defined here: The following directions, up, down, left, right, and back, are the same as the top, bottom, left, right, front, and back directions of the projection relationship shown in Figure 1.

1 to 4, a quick flux facility according to an embodiment of the present invention includes an apparatus main body 100, and a first empty cavity 127 opened upward is installed in the apparatus main body 100. A first transmission cavity 122 located on the right side of the first empty cavity 127 is installed therein, and a first rotation extending left and right is provided between the first transmission cavity 122 and the first empty cavity 127. A shaft 129 is engaged and mounted so as to rotate, and a left end of the first rotation shaft 129 is engaged and connected to a left end wall of the first empty cavity 127 so as to rotate. Is provided with a first crushing wheel 128 fixedly mounted on the outer surface of the first rotating shaft 129, and a first fixedly mounted on the right end of the first rotating shaft 129 in the first transmission cavity 122. A spur gear 121 is installed, and in the apparatus main body 100, the first A second transmission cavity 123 located between the cavity and the first transmission cavity 122 is installed, and the first rotation shaft 129 passes through the second transmission cavity 123 so as to rotate; A second spur gear 124 that is fixedly attached to the outer surface of the first rotary shaft 129 is installed in 123, and extends between the second transmission cavity 123 and the first empty cavity 127 to the left and right. The second rotary shaft 151 is engaged and mounted so as to rotate, and the second rotary shaft 151 is positioned on the rear side of the first rotary shaft 129, and the left end of the second rotary shaft 151 is the first rotary shaft 129. A third spur gear 152, which is engaged and connected to the left end wall of the empty cavity 127 so as to be rotatable, is fixedly mounted on the outer surface of the second rotating shaft 151 in the second transmission cavity 123, and The third spur gear 152 and the second spur gear 124 mesh, A second crushing wheel 150 that is fixedly attached to the outer surface of the second rotating shaft 151 and that engages with the first crushing wheel 128 is installed in the empty cavity 127. A third transmission cavity 115 located on the right side of one transmission cavity 122 is installed, and a third rotating shaft 117 extending in the left and right direction can rotate between the third transmission cavity 115 and the first transmission cavity 122. In the first transmission cavity 122, an irregular spur gear 120 fixedly mounted on the left end of the third rotating shaft 117 is installed, and the irregular spur gear 120 is connected to the first spur gear 121. A first bevel gear 116 fixedly mounted on the right end of the third rotating shaft 117 is installed in the third transmission cavity 115, and the third transmission gear 115 is installed in the device main body 100. Fourth transmission cavity 105 located below cavity 115 An upper end of the third transmission cavity 115 is installed between the third transmission cavity 115 and the fourth transmission cavity 105 so that a fourth rotating shaft 110 extending vertically can be rotated. A rotation motor 119 is fixedly mounted in the wall, and an upper end of the fourth rotation shaft 110 is connected to the rotation motor 119, and a lower end of the fourth rotation shaft 110 is connected to a lower end wall of the fourth transmission cavity 105. A second bevel gear 118 is fixedly mounted in the third transmission cavity 115 so as to be able to rotate, and is positioned on the outer surface of the fourth rotation shaft 110 and meshes with the first bevel gear 116. A second empty cavity 132 located below the first empty cavity 127 is installed in the apparatus main body 100, and a right end wall of the second empty cavity 132 communicates with the fourth transmission cavity 105. , The first empty cavity 127 and the second empty cavity A third empty cavity 131 is installed in communication with the tee 132, and a transmission mounting block 103 is fixedly mounted in the second empty cavity 132 by a connection bracket in the second empty cavity 132. A cylindrical rotating block 133 is rotatably mounted on the upper end of the transmission mounting block 103, and a tapered inclined surface is installed on the upper end of the cylindrical rotating block 133; An annular rotary block 136 is engaged and mounted on the upper side of the inner wall of 132, and an inclined surface extending to the cylindrical rotary block 133 is installed on the upper end surface of the annular rotary block 136, and the second empty cavity An annular groove 134 is provided in communication with the inner wall of 132, and an outer gear 135 that is fixedly attached to the outer surface of the annular rotary block 136 is installed in the annular groove 134. 100 includes a fifth transmission cavity 112 positioned between the third transmission cavity 115 and the fourth transmission cavity 105, so that the fourth rotation shaft 110 can rotate the fifth transmission cavity 112. A first transmission wheel 111 fixedly mounted on the outer surface of the fourth rotating shaft 110 is installed in the fifth transmission cavity 112, and a sixth transmission cavity is formed on the right end wall of the annular groove 134. 162 is communicated, and the sixth transmission cavity 162 is positioned below the fifth transmission cavity 112, and a fifth rotating shaft is provided between the sixth transmission cavity 162 and the fifth transmission cavity 112. 160 is engaged so as to be able to rotate , and in the fifth transmission cavity 112, a second transmission wheel 114 fixedly mounted on the upper end of the fifth rotation shaft 160 is installed, and the first transmission wheel 111 and is first transmission belt 113 transmission is between the second transmission gear 114 It is connected in order to be able, above in the sixth transmission cavity 162 fourth spur gear 161 which meshes with the lower end being fixedly attached and out the ring gear 135 of the fifth rotary shaft 160 is installed, the cylindrical rotary block 133 The crushing block 141 is installed on each of the outer circumferential surface and the inner circumferential surface of the annular rotary block 136, and the crushing block 141 and the annular rotary block 136 on the outer circumferential surface of the cylindrical rotary block 133 are arranged. The position of the crushing block 141 on the circumferential surface is shifted up and down, and in the second empty cavity 132, a filtration device 142 fixedly mounted on the lower outer surface of the cylindrical rotating block 133 is installed, One end of the filtering device 142 remote from the cylindrical rotary block 133 is in contact with the annular rotary block 136, and an open groove 138 opened upward is installed in the transmission mounting block 103. The sixth rotary shaft 137 extending upward is engaged and mounted on the lower end wall of 8, and the sixth rotary shaft 137 is inserted into the cylindrical rotary block 133 so as to rotate the cylindrical shape. A communication groove 104 communicating with the second empty cavity 132 is installed in the right end wall of the open groove 138 in fixed engagement with the rotary block 133, and the sixth rotation is provided in the open groove 138. A third transmission wheel 139 fixedly mounted on the outer surface of the shaft 137 is installed, and a fourth transmission wheel 109 fixedly mounted on the outer surface of the fourth rotating shaft 110 is installed in the fourth transmission cavity 105. The second transmission belt 106 is connected between the third transmission wheel 139 and the fourth transmission wheel 109 so that the second transmission belt 106 can be transmitted. A lower opening 102 located at A cavity 101 is installed in communication.

As shown as a useful example, an inlet mounting block 126 positioned above the first empty cavity 127 is fixedly attached to an upper end of the apparatus body 100, and the first empty space is inserted in the inlet mounting block 126. A flux inlet 125 penetrating up and down communicating with the cavity 127 is installed, and a slope extending in the direction of the first empty cavity 127 is installed at the flux inlet 125, thereby providing convenience for adding the flux raw material. .

As a useful example, a heating resistance wire 143 is fixedly attached to the opposite end faces of the annular rotary block 136 and the cylindrical rotary block 133, and the second empty cavity is fixed by the heating resistance wire 143. The drying operation is performed on the flux in 132.

As a useful example, a symmetrical mounting base 108 is fixedly attached to the lower end wall of the apparatus main body 100, and a support base 107 is fixedly attached to the lower end of the mounting base 108. Increase the stability when the device is operating.

When in the initial state, the rotary motor 119 is in an off state, and at this time, the gear portion of the irregular spur gear 120 meshes with the first spur gear 121, and the cylindrical rotary block 133 and the annular rotary block 136 The first crushing wheel 128 and the second crushing wheel 150 are relatively stationary in the first empty cavity 127 at the same time.

When used, an operator adds a flux raw material into the first empty cavity 127 via the flux inlet 125, and at this time starts the rotary motor 119, and the rotary motor 119 is moved to the fourth rotary shaft. The second bevel gear 118 is moved and rotated through 110, the second bevel gear 118 is rotated by rotating the third rotating shaft 117 according to the meshing relationship with the first bevel gear 116, and the third rotation A shaft 117 moves and rotates the first rotating shaft 129 according to the meshing relationship between the irregular spur gear 120 and the first spur gear 121, and the first rotating shaft 129 moves the first crushing wheel 128. At the same time, the first rotating shaft 129 moves and rotates the second crushing wheel 150 by the meshing relationship between the second spur gear 124 and the third spur gear 152, and at this time, the first crushing wheel 128 and the second crushing wheel 150 are arranged in the first empty cavity 127. First, the flux material subjected to the initial polishing falls into the second empty cavity 132 through the third empty cavity 131, and at this time, the fourth rotating shaft 110 Moves and rotates the fifth rotating shaft 160 through the engagement of power between the first transmission wheel 111 and the second transmission wheel 114, and the fifth rotating shaft 160 is connected to the fourth spur gear 161 and the The annular rotary block 136 is moved and rotated through the meshing relationship with the outer gear 135, and at the same time, the fourth rotary shaft 110 is engaged with the power between the fourth transmission wheel 109 and the third transmission wheel 139. The sixth rotary shaft 137 is moved and rotated through the sixth rotary shaft 137, the sixth rotary shaft 137 moves and rotates the cylindrical rotary block 133, and the rotating direction of the cylindrical rotary block 133 and the annular rotary block 136 are At this time, the cylindrical rotary block 133 and the crushing block 141 on the outer surface of the annular rotating block 136, the flux raw material is subjected to final polishing, and at the same time, the heating resistance wire 143 is activated to cause the flux in the second empty cavity 132 to flow. The dried and processed flux is discharged from the outlet 102 via the filtering device 142 and the fourth empty cavity 101.

The present invention is simple in structure, easy to operate, and completes each step from flux polishing to drying, etc. by a closely assembled transmission structure, thereby providing convenient use of the flux, and by secondary polishing on the flux The final granularity of the final flux product is made finer, the polishing and drying crafts for flux are advanced simultaneously, the flux processing efficiency is increased, and the flux material is made more convenient through the slope installed at the entrance. In addition, the support platform enhances the stability during operation of the device, thereby increasing the effect of using the flux.

An engineer in this field can clarify the case where it does not depart from the general spirit and idea of the present invention. Various modifications can be made to the above-described embodiments, and these modifications are all within the protection scope of the present invention. The protection scheme of the present invention should be based on the rights claim of the present invention.

Claims (1)

Including a device main body, a first empty cavity opened upward in the device main body, a first transmission cavity located on the right side of the first empty cavity is installed in the device main body, Between the first transmission cavity and the first empty cavity, a first rotating shaft extending from side to side is engaged and mounted so as to rotate, and the left end of the first rotating shaft can be rotated. A first crushing wheel is installed in engagement with the left end wall of the first empty cavity, and is fixedly mounted on the outer surface of the first rotating shaft. Has a first spur gear fixedly attached to the right end of the first rotating shaft, and a second transmission cavity located between the first empty cavity and the first transmission cavity in the apparatus main body. And the first rotation Passes through the second transmission cavity, and a second spur gear fixedly mounted on the outer surface of the first rotating shaft is installed in the second transmission cavity, and the second transmission cavity A second rotary shaft extending to the left and right is engaged and mounted between the first empty cavity, and the second rotary shaft is located on the rear side of the first rotary shaft, A third flat shaft is engaged and connected so that the left end of the second rotary shaft can rotate with the left end wall of the first empty cavity, and is fixedly mounted on the outer surface of the second rotary shaft in the second transmission cavity. A gear is installed, the third spur gear and the second spur gear mesh with each other, and the first empty cavity is fixedly attached to the outer surface of the second rotating shaft and is engaged with the first crushing wheel. A second crushing wheel is installed, and in the device body, the first crushing wheel A third transmission cavity located on the right side of the moving cavity is installed, and a third rotary shaft extending from side to side is engaged and mounted between the third transmission cavity and the first transmission cavity so as to rotate. In the first transmission cavity, an irregular spur gear fixedly attached to the left end of the third rotating shaft is installed, and the irregular spur gear can mesh with the first spur gear, and the third transmission cavity A first bevel gear fixedly mounted on the right end of the third rotating shaft is installed in the device body, a fourth transmission cavity located below the third transmission cavity is installed in the device body, A fourth rotary shaft extending vertically is engaged and mounted between the third transmission cavity and the fourth transmission cavity, and a rotary motor is disposed in the upper end wall of the third transmission cavity. Solid Fixedly mounted, the lower end of the rotary motor and the fourth rotating shaft are connected , and the lower end of the fourth rotating shaft is engaged and connected so as to rotate with the lower end wall of the fourth transmission cavity, and the third transmission A second bevel gear located on the outer surface of the fourth rotating shaft and meshing with the first bevel gear is fixedly mounted in the cavity, and is positioned below the first empty cavity in the apparatus body. A second empty cavity is installed, the right end wall of the second empty cavity communicates with the fourth transmission cavity, and a third empty cavity is formed between the first empty cavity and the second empty cavity. disposed in communication with said second air cavity in the installed transmission mounting block fixed mounted in the second air cavity by a connecting bracket, the transmission mounting cylindrical rotary block to the upper end of the block Is engaged mounted for rotation, the upper end of the cylindrical rotary block is installed tapered inclined surface, the inner wall above the second air cavity is mounted engages so that it can rotate the annular rotating block, the An inclined surface extending to the cylindrical rotary block is installed at the upper end surface of the annular rotary block, and an annular groove is installed in the inner wall of the second empty cavity. An outer gear fixedly mounted on the outer surface of the annular rotary block is installed, and a fifth transmission cavity located between the third transmission cavity and the fourth transmission cavity is installed in the apparatus body, A fourth transmission shaft passes through the fifth transmission cavity so that it can rotate, and a first transmission wheel fixedly mounted on the outer surface of the fourth rotation shaft is installed in the fifth transmission cavity. , The right end wall of the annular groove is disposed in communication with the sixth transmission cavity, a and the sixth transmission cavity is positioned below the fifth transmission cavity, wherein the sixth transmission cavity fifth transmission cavity A fifth transmission shaft is engaged and connected between the second transmission wheel and a second transmission wheel fixedly mounted on an upper end of the fifth rotation shaft is installed in the fifth transmission cavity. A first transmission belt is connected between the transmission wheel and the second transmission wheel so as to be able to transmit , and the sixth transmission cavity is fixedly attached to the lower end of the fifth rotating shaft, and the outer gear Meshing fourth spur gears are installed, crushing blocks are respectively installed on the outer circumferential surface of the cylindrical rotary block and the inner circumferential surface of the annular rotary block, and the outer circumferential surface of the cylindrical rotary block Crushing block And the crushing block on the inner circumferential surface of the annular rotating block is displaced up and down, and in the second empty cavity, there is a filtration device fixedly mounted on the lower side of the outer surface of the cylindrical rotating block. One end of the filtering device that is far from the cylindrical rotary block is in contact with the annular rotary block, and an open groove that opens upward is installed in the transmission mounting block, and a lower end wall of the open groove The sixth rotary shaft extending upward is engaged and mounted so as to be rotatable, and the sixth rotary shaft is inserted into the cylindrical rotary block and fixedly engaged with the cylindrical rotary block. A third transmission that is connected and is provided in the right end wall of the open groove to communicate with the second empty cavity, and is fixedly mounted on the outer surface of the sixth rotary shaft in the open groove. A wheel is installed and the fourth transmission key Some Activity placed fourth transmission wheel which is fixedly mounted to the outer surface of the fourth rotary shaft, between the said third driving wheel and the fourth gear train to allow transmission the second transmission belt The apparatus body is provided with a downwardly opened outlet located below the second empty cavity, and a fourth empty cavity communicates between the outlet and the second empty cavity. An inlet mounting block located above the first empty cavity is fixedly attached to the upper end of the apparatus main body, and the inlet mounting block penetrates up and down to communicate with the first empty cavity. A flux inlet is installed, and a slope extending in the direction of the first empty cavity is installed at the flux inlet, thereby providing convenience for adding a flux raw material, the annular rotating block and the cylindrical shape A heating resistance wire is fixedly mounted on the end face facing the rolling block, the heating resistance wire performs a drying operation on the flux in the second empty cavity, and the lower end wall of the apparatus main body is mount of symmetry is fixed mounted, wherein the mounting base of the lower support stand is fixed mounted, quick flux equipment, characterized in that said support pedestal is increased stability when the device is operated.

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