JP2021020208A - Collection and disposal facility for waste rich in nutrient component in beer factory - Google Patents

Abstract

To disclose a collection and disposal facility for waste rich in nutrient components in a beer factory.SOLUTION: A collection and disposal facility for waste rich in nutrient components in a beer factory includes a dry oven. A dehydration space opened upward is installed on an upper end face of the dry oven, and a dehydration mechanism is installed in the dehydration space. A base is installed in the dehydration mechanism, and a rotatable dehydration tub is installed in the base. A columnar space penetrating through upper and lower end faces of the dehydration tub is installed in the dehydration tub, and a number of small holes are provided in the dehydration tub. Waste in a beer factory is put into the columnar space, and moisture contained in the waste in the beer factor can be removed rapidly by whirling the dehydration tub. A tilting mechanism is installed at the left side of the dehydration mechanism. After large quantities of moisture in the columnar space is removed, the tilting mechanism starts to operate to allow the dehydration mechanism to move upward and rotate in tandem, so that the waste in the columnar space is pushed out.SELECTED DRAWING: Figure 1

Description

The present invention relates to the field of waste recovery, and specifically to a waste recovery and processing facility rich in nutrients in a beer factory.

Along with social development, beer promoted the rapid development of the Japanese beer industry as a blockbuster product on hot summer days, while also promoting the formation of large amounts of nutrient-rich waste. Wastes with a high water content have a certain value in use, and if they are not dried promptly, they will ferment and spoil. Most of the waste from beer factories is viscous, and the efficiency is low with a general dehydration method. Moreover, some of the water contained in the waste needs to be removed by a heat-drying method. Low efficiency.

Publication No. 103962365 of Chinese Patent Application

We will solve the above problems by providing a waste collection and treatment facility rich in nutrients in beer factories.

A waste collection and processing facility rich in nutrients in a beer factory, including a dryer, a dehydration space opened upward is installed on the upper end surface of the dryer, and a dehydration mechanism is provided in the dehydration space. A base is installed in the dehydration mechanism, a rotatable dehydration tub is installed in the base, and a cylindrical space penetrating the upper and lower end surfaces of the dehydration tub is installed in the dehydration tub. A large number of small holes are installed in the dehydration tub, and the waste of the beer factory is put into the cylindrical space, and the water content in the waste of the beer factory is quickly increased by the rotation of the dehydration tub. Can be removed
A tilting mechanism is installed on the left side of the dehydration mechanism, and after most of the water in the cylindrical space is removed, the tilting mechanism starts to operate, and the dehydration mechanism is interlocked to ascend and rotate. , The waste in the cylindrical space is extruded,
A drying mechanism is installed on the right side of the tilting mechanism, the drying mechanism includes an inclined space located in the right end wall of the dehydration space, and a drying pipe communicating with the outside is attached to the right end wall of the inclined space. A plurality of small holes are installed in the drying pipe, a hot air block is installed on the upper side of the drying pipe, the hot air block can completely dry waste, and the rotation of the spiral block in the drying pipe allows the waste to be completely dried. , The dried waste can be discharged to the outside.

Advantageously, the dehydration mechanism includes an operating space located on the lower end wall of the dehydration space, a dehydration motor is fixedly installed on the right side of the lower end wall of the operating space, and dehydration is performed on the upper end surface of the dehydration motor. The shaft is rotatably installed, the upper end of the dehydration shaft is located in the dehydration space, the first pulley is fixedly installed on the dehydration shaft in the working space, and the first pulley is fixedly installed in the dehydration space. Two transmission rods are fixedly installed on the dehydration shaft, a rotation space opened upward and to the left is installed on the right end wall of the dehydration space, and a rotation space opens forward on the rear end wall of the rotation space. A bottom space is installed, a spherical block is installed in the bottom space, a support rod is fixedly installed on the left end surface of the spherical block, and the left end of the support rod is in the dehydration space. Positioned, the base is fixedly installed at the left end of the support rod, an annular groove is formed in the base, and an arcuate rod is installed symmetrically and slidably in the annular groove. , The dehydration tub is fixedly installed between the two arcuate rods.

Advantageously, the guide rods are symmetrically and fixedly installed on the left and right end walls of the cylindrical space, and a circular block is slidably installed in the cylindrical space by two guide rods. A circular space opened downward is installed on the lower end surface of the block, four force receiving blocks are fixedly installed at equal intervals in the circular space, and an elastic plate is provided in the force receiving block by an elastic torsion spring. Is rotatably installed, the transmission rod is embedded in the circular space, and the two elastic plates are pushed and moved to rotate, and an elastic groove opened to the left in the right end wall of the rotating space. Is formed, an elastic spring is fixedly installed on the right end wall of the elastic groove, and an elastic rod slidably connected to the elastic groove is fixedly installed on the left end of the elastic spring.

Advantageously, the tilting mechanism includes a pressure space that opens upward, the pressure space is located in the lower end wall of the dehydration space, and the rear end wall of the pressure space communicates with the outside by an outlet. A localization rod is fixedly installed on the rear end wall of the pressure space, a pressure plate is rotatably installed on the localization rod by a pressure torsion spring, and a transmission groove is formed in the left end wall of the pressure space. Is formed, the lower end wall of the transmission groove communicates with the operating space, a long rack is slidably installed in the left end wall of the pressure space, and the left end of the long rack is in the transmission groove. The transmission gear is installed so as to mesh with the lower side of the long rack, and the short rack slidably connected to the transmission groove is installed so as to mesh with the lower side of the transmission gear. The left end surface of the short rack is fixedly connected to the left end wall of the transmission groove by a lateral spring, a top shaft is rotatably installed on the lower end surface of the short rack, and the lower end of the top shaft is the working space. A large gear is fixedly installed on the top shaft, a second pulley is fixedly installed on the lower end of the top shaft, and the second pulley and the first pulley are fixedly installed by a belt. Friction transmission is possible.

Beneficially, a square space is installed in the upper end wall of the working space, the right end wall of the square space communicates with the dehydrated space, and the output shaft is rotatable on the lower end wall of the working space. Installed, the upper end of the output shaft is located in the square space, a small gear is fixedly installed on the output shaft in the working space, and a first bevel gear is installed on the upper end of the output shaft. It is fixedly installed, a square frame is slidably installed in the square space, a horizontal rod is fixedly installed on the right end surface of the square frame, and the right end of the horizontal rod is in the dehydration space. A thrust plate is fixedly installed at the right end of the lateral rod, a rotating shaft is rotatably installed on the rear end wall of the square space, and a half gear and a second bevel gear are installed on the rotating shaft. Is fixedly installed, the second cap gear is located on the front side of the half gear, the second cap gear and the first cap gear can be meshed and transmitted, and when the half gear rotates, the square frame and Can mesh.

The tilting mechanism includes a funnel mounted on the right side of the upper end surface of the dryer, the funnel communicates with the tilted space, and a power motor is fitted in the left end wall of the tilted space. A drive shaft is rotatably installed on the right end surface of the power motor, the spiral block is fixedly installed on the drive shaft, a dry space is installed in the right end wall of the inclined space, and the dry space is installed. The hot air block is attached to the upper end surface of the space, and a guide tube communicating with the outside is attached to the lower end wall of the drying space.

The lateral spring and the elastic spring are in a normal state.

The beneficial effect of the present invention is: The present invention quickly dehydrates the waste in a centrifugal method with respect to the water content and consistency of the waste in the beer factory, improves the waste recovery efficiency, and dehydrates to a certain extent. After that, it is automatically discharged and dried, and the drying area is increased by spiral injection, the drying is accelerated, the recovery efficiency is further improved, and the subsequent recovery is convenient.

In order to explain the present invention in detail with reference to FIGS. 1 to 4 below and to explain the present invention in a convenient manner, the following directions are defined as follows: FIG. 1 is a front view of the apparatus of the present invention and is described in the present application. Each direction is the direction when the device is viewed in the same direction as in FIG.

FIG. 1 is a front view of the entire cross section of the present invention. FIG. 2 is an enlarged configuration diagram of A in FIG. FIG. 3 is an enlarged configuration diagram of B in FIG. FIG. 4 is a block diagram in the CC direction in FIG.

As shown in FIGS. 1 to 4, it is a waste collection and processing facility rich in nutrient components of a brewery, and includes a dryer 10, and a dehydration space 18 opened upward is provided on the upper end surface of the dryer 10. A dehydration mechanism 80 is installed in the dehydration space 18, a base 20 is installed in the dehydration mechanism 80, a rotatable dehydration tub 23 is installed in the base 20, and the dehydration is performed. A cylindrical space 24 penetrating the upper and lower end surfaces of the dehydration tub 23 is installed in the tub 23, and a large number of small holes are installed in the dehydration tub 23 to collect waste from a beer factory into the columnar space. By putting it in 24 and rotating the dehydration tub 23, the water contained in the waste of the beer factory can be quickly removed.
A tilting mechanism 81 is installed on the left side of the dehydration mechanism 80, and after most of the water in the cylindrical space 24 is removed, the tilting mechanism 81 starts to operate, and the dehydration mechanism 80 is interlocked with the tilting mechanism 80. Ascended and rotated, the waste in the cylindrical space 24 is pushed out,
A drying mechanism 82 is installed on the right side of the tilting mechanism 81, and the drying mechanism 82 includes an inclined space 32 located in the right end wall of the dehydration space 18, and communicates with the outside on the right end wall of the inclined space 32. The drying pipe 35 is attached, a plurality of small holes are installed in the drying pipe 35, a hot air block 33 is installed on the upper side of the drying pipe 35, and the hot air block 33 can completely dry the waste. By rotating the spiral block 34 in the drying pipe 35, the dried waste can be discharged to the outside.

Advantageously, the dehydration mechanism 80 includes an operating space 47 located on the lower end wall of the dehydration space 18, and a dehydration motor 42 is fixedly installed on the right side of the lower end wall of the operating space 47. A dehydration shaft 43 is rotatably installed on the upper end surface of the 42, the upper end of the dehydration shaft 43 is located in the dehydration space 18, and the first pulley 44 is on the dehydration shaft 43 in the working space 47. Is fixedly installed, two transmission rods 61 are fixedly installed on the dehydration shaft 43 in the dehydration space 18, and a rotating space opened upward and to the left on the right end wall of the dehydration space 18. 26 is installed, a bottom space 27 opened forward is installed on the rear end wall of the turning space 26, a spherical block 40 is installed in the bottom space 27, and the left end surface of the spherical block 40 is installed. A support rod 41 is fixedly installed in the support rod 41, the left end of the support rod is located in the dehydration space 18, and the base 20 is fixedly installed at the left end of the support rod 41. An annular groove 22 is formed in the annular groove 22, and an arcuate rod 21 is installed symmetrically and slidably in the annular groove 22, and the dehydration tub 23 is fixedly installed between the two arcuate rods 21. Installed,
Guide rods 25 are symmetrically and fixedly installed on the left and right end walls of the cylindrical space 24, and circular blocks 67 are slidably installed in the cylindrical space 24 by two guide rods 25, and the circular shape is formed. A circular space 66 opened downward is installed on the lower end surface of the block 67, and four force receiving blocks 64 are fixedly installed in the circular space 66 at equal intervals, and the force receiving block 64 has elasticity. The elastic plate 62 is rotatably installed by the torsion spring 63, the transmission rod 61 is charged in the circular space 66, and the two elastic plates 62 are pushed and moved to rotate, and the right end wall of the rotating space 26 is formed. An elastic groove 30 that opens to the left is formed in the inside, an elastic spring 29 is fixedly installed on the right end wall of the elastic groove 30, and the elastic groove 30 is slidable on the left end of the elastic spring 29. The elastic rod 28 connected to the above is fixedly installed.

Beneficially, the tilting mechanism 81 includes a pressure space 59 that opens upward, the pressure space 59 is located in the lower end wall of the dehydration space 18, and the rear end wall of the pressure space 59 is an outlet 58. A localization rod 56 is fixedly installed on the rear end wall of the pressure space 59, and a pressure plate 57 is rotatably installed on the localization rod 56 by a pressure torsion spring 55. A transmission groove 51 is formed in the left end wall of the pressure space 59, the lower end wall of the transmission groove 51 communicates with the operating space 47, and a long rack 54 is in the left end wall of the pressure space 59. It is slidably installed, the left end of the long rack 54 is located in the transmission groove 51, and the transmission gear 68 is installed below the long rack 54 so as to mesh with the transmission gear 68. Is movably installed so that the short rack 53 slidably connected to the transmission groove 51 meshes with the transmission groove 51, and the left end surface of the short rack 53 is fixedly connected to the left end wall of the transmission groove 51 by a lateral spring 52. A top shaft 50 is rotatably installed on the lower end surface of the short rack 53, the lower end of the top shaft 50 is located in the working space 47, and a large gear 60 is fixed to the top shaft 50. The second pulley 46 is fixedly installed at the lower end of the top shaft 50, and the second pulley 46 and the first pulley 44 can be frictionally transmitted by the belt 45.
A square space 16 is installed in the upper end wall of the working space 47, the right end wall of the square space 16 communicates with the dehydration space 18, and the output shaft 48 rotates on the lower end wall of the working space 47. The output shaft 48 is possibly installed, the upper end of the output shaft 48 is located in the square space 16, and a small gear 49 is fixedly installed in the output shaft 48 in the working space 47. The first bevel gear 11 is fixedly installed at the upper end, the square frame 15 is slidably installed in the square space 16, and the lateral rod 17 is fixedly installed on the right end surface of the square frame 15. The right end of the lateral rod 17 is located in the dehydration space 18, a thrust plate 19 is fixedly installed at the right end of the lateral rod 17, and a rotation shaft 12 is installed on the rear end wall of the square space 16. Is rotatably installed, a half gear 14 and a second cap gear 13 are fixedly installed on the rotating shaft 12, and the second cap gear 13 is located on the front side of the half gear 14, and the second The bevel gear 13 and the first bevel gear 11 can be meshed and transmitted, and the half gear 14 can be engaged with the square frame 15 when rotated.

Beneficially, the tilting mechanism 81 includes a funnel 31 mounted on the right side of the upper end surface of the dryer 10, the funnel 31 communicating with the tilted space 32, and a left end wall of the tilted space 32. A power motor 39 is fitted therein, a drive shaft 38 is rotatably installed on the right end surface of the power motor 39, and the spiral block 34 is fixedly installed on the drive shaft 38 to form the inclined space. A drying space 36 is installed in the right end wall of the 32, the hot air block 33 is attached to the upper end surface of the drying space 36, and a guide pipe 37 communicating with the outside is attached to the lower end wall of the drying space 36. Has been done.

Advantageously, the lateral spring 52 and the elastic spring 29 are in a normal state.

Order of machine operation throughout the device:
(1) The waste of the beer factory is tilted into the cylindrical space 24, and the wastewater inside flows out and pushes the pressure plate 57 to rotate, so that the long rack 54 moves to the left and the wastewater flows from the discharge port 58. Due to the meshing of the long rack 54 and the transmission gear 68, the transmission gear 68 rotates to move the short rack 53 to the right and interlock with the flow, so that the large gear 60 does not mesh with the small gear 46.
(2) The dehydration motor 42 is started, the dehydration shaft 43 rotates in conjunction with each other, the first pulley 44 and the transmission rod 61 also rotate in conjunction with each other, and the dehydration tub 23 is transmitted by the transmission between the transmission rod 61 and the elastic plate 62. Rotates to centrifuge and dehydrate beer factory waste.
(3) When the majority of the water in the waste of the beer factory is removed, the pressure plate 57 returns and the short rack 53 returns and interlocks, the large gear 60 returns and meshes with the small gear 49, and the belt. 45 is pulled, the first pulley 44 rotates and interlocks the second pulley 46 by the friction transmission of the belt 45, and therefore the large gear 60 rotates, and the mesh transmission of the large gear 60 and the small gear 49 causes the first bevel gear. 11 rotates, and the meshing transmission between the first gear and the second gear 13 causes the second gear 13 to rotate and the half gear 14 to rotate and interlock, and the half gear 14 and the square frame 15 mesh with each other. The square frame 15 first moves to the right, the thrust plate 19 moves to the right according to the square frame 15 and pushes the base 20 to raise it, so that the transmission rod 61 separates from the circular space 66.
(4) The spherical block 40 rises according to the base 20, the thrust plate 19 pushes and rotates the base 20, the dehydration tub 23 and the support rod 41 rotate, and the support rod 41 pushes the elastic rod 28 to the right. The elastic spring 29 is compressed, the thrust plate 19 pushes and moves the circular block 67, and the dehydrated beer factory waste in the cylindrical space 24 is pushed into the funnel 31 to move the inclined space 32. Go inside.
(5) The power motor 39 and the hot air block 33 are activated, the hot air block 33 generates heat, the power motor 39 rotates and interlocks the drive shaft 38, and the waste of the beer factory in the inclined space 32 is spirally discharged. Then, the hot air block 33 dries the waste of the beer factory in the drying pipe 35, and the dried waste of the beer factory is discharged to the outside and collected and used for other industries.

According to the above method, those skilled in the art can carry out various changes according to the operation pattern within the scope of the present invention.

Claims (7)

A waste collection and processing facility rich in nutrients in a beer factory, including a dryer,
A dehydration space opened upward is installed on the upper end surface of the dryer, a dehydration mechanism is installed in the dehydration space, a base is installed in the dehydration mechanism, and rotation is performed in the base. A dehydration tub that can be used is installed, a cylindrical space that penetrates the upper and lower ends of the dehydration tub is installed in the dehydration tub, and a large number of small holes are installed in the dehydration tub, which is waste from a beer factory. Can be quickly removed from the waste of the beer factory by turning the dehydration tub in the cylindrical space.
A tilting mechanism is installed on the left side of the dehydration mechanism, and after most of the water in the cylindrical space is removed, the tilting mechanism starts to operate, and the dehydration mechanism is interlocked to ascend and rotate. , The waste in the cylindrical space is extruded,
A drying mechanism is installed on the right side of the tilting mechanism, the drying mechanism includes an inclined space located in the right end wall of the dehydration space, and a drying pipe communicating with the outside is attached to the right end wall of the inclined space. A plurality of small holes are installed in the drying pipe, a hot air block is installed on the upper side of the drying pipe, the hot air block can completely dry the waste, and the rotation of the spiral block in the drying pipe allows the waste to be completely dried. A waste collection and treatment facility rich in nutrients in beer factories, which is characterized by being able to discharge dried waste to the outside. The dehydration mechanism includes an operating space located on the lower end wall of the dehydration space, a dehydration motor is fixedly installed on the right side of the lower end wall of the operating space, and a dehydration shaft can rotate on the upper end surface of the dehydration motor. The upper end of the dehydration shaft is located in the dehydration space, and a first pulley is fixedly installed on the dehydration shaft in the working space and on the dehydration shaft in the dehydration space. Two transmission rods are fixedly installed, a rotating space opened upward and to the left is installed on the right end wall of the dehydration space, and a bottom space opened forward is installed on the rear end wall of the rotating space. A spherical block is installed in the bottom space, a support rod is fixedly installed on the left end surface of the spherical block, and the left end of the support rod is located in the dehydration space. The base is fixedly installed at the left end of the support rod, an annular groove is formed in the base, and an arcuate rod is installed symmetrically and slidably in the annular groove. The facility for collecting and treating nutrient-rich waste from a brewery according to claim 1, wherein the dehydration tub is fixedly installed between the arc-shaped rods. Guide rods are symmetrically and fixedly installed on the left and right end walls of the cylindrical space, and a circular block is slidably installed in the cylindrical space by two guide rods on the lower end surface of the circular block. A circular space opened downward is installed, four force receiving blocks are fixedly installed in the circular space at equal intervals, and an elastic plate is rotatably installed in the force receiving block by an elastic torsion spring. The transmission rod is inserted into the circular space and the two elastic plates are pushed and rotated to rotate, and an elastic groove opened to the left is formed in the right end wall of the rotating space. The claim is characterized in that an elastic spring is fixedly installed on the right end wall of the elastic groove, and an elastic rod slidably connected to the elastic groove is fixedly installed on the left end of the elastic spring. A waste collection and treatment facility rich in nutrients in the beer factory described in 2. The tilting mechanism includes a pressure space opened upward, the pressure space is located in the lower end wall of the dehydration space, and the rear end wall of the pressure space communicates with the outside by a discharge port. A localization rod is fixedly installed on the rear end wall, a pressure plate is rotatably installed on the localization rod by a pressure torsion spring, and a transmission groove is formed in the left end wall of the pressure space. The lower end wall of the transmission groove communicates with the operating space, a long rack is slidably installed in the left end wall of the pressure space, and the left end of the long rack is located in the transmission groove. A transmission gear is installed on the lower side of the long rack so as to mesh with each other, and a short rack slidably connected to the transmission groove is installed on the lower side of the transmission gear so as to mesh with each other. The left end surface is fixedly connected to the left end wall of the transmission groove by a lateral spring, a top shaft is rotatably installed on the lower end surface of the short rack, and the lower end of the top shaft is located in the working space. A large gear is fixedly installed on the top shaft, a second pulley is fixedly installed on the lower end of the top shaft, and the second pulley and the first pulley can be frictionally transmitted by a belt. The waste collection and processing facility rich in nutritional components of the beer factory according to claim 1. A square space is installed in the upper end wall of the working space, the right end wall of the square space communicates with the dehydration space, and an output shaft is rotatably installed on the lower end wall of the working space. The upper end of the output shaft is located in the square space, the small gear is fixedly installed on the output shaft in the working space, and the first bevel gear is fixedly installed on the upper end of the output shaft. A square frame is slidably installed in the square space, a horizontal rod is fixedly installed on the right end surface of the square frame, and the right end of the horizontal rod is located in the dehydration space. A thrust plate is fixedly installed at the right end of the lateral rod, a rotating shaft is rotatably installed on the rear end wall of the square space, and a half gear and a second bevel gear are fixed to the rotating shaft. The second bevel gear is located on the front side of the half gear, the second bevel gear and the first bevel gear can be engaged and transmitted, and the half gear can be engaged with the square frame when rotated. The waste collection and processing facility rich in nutrient components of the beer factory according to claim 4, wherein the waste is collected and processed. The tilting mechanism includes a funnel mounted on the right side of the upper end surface of the dryer, the funnel communicates with the tilted space, and a power motor is fitted in the left end wall of the tilted space. A drive shaft is rotatably installed on the right end surface of the power motor, the spiral block is fixedly installed on the drive shaft, a dry space is installed in the right end wall of the inclined space, and the dry space is installed. The nutritional component-rich disposal of the beer factory according to claim 1, wherein the hot air block is attached to the upper end surface of the space, and a guide tube communicating with the outside is attached to the lower end wall of the drying space. Collection processing equipment for goods. The nutrient-rich waste collection and treatment equipment for a beer factory according to claim 4, wherein the lateral spring and the elastic spring are in a normal state.

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