JP2021071040A - Quartz stone material spreader device - Google Patents

Abstract

To disclose a quartz stone material spreader device according to the invention of the present application.SOLUTION: An outer shell is included and a working space is arranged in the outer shell; a T-shaped slide groove is formed on an upper inner wall of the working space; and a laterally moving member is arranged in the T-shaped slide groove. The invention of the present application uses a unidirectional bearing and thus some of the members do not move in the initial state. The stone material leveling work is thus divided into several steps by using a groove wheel. A sufficient storage space is secured when dropping the stone material by using the stone material leveling hopper, so that the stone material leveling work is guaranteed to proceed smoothly. Currently, most quartz stone material spreader devices lay the stone material directly from a container without any intermediate medium at the time of laying out the stone material. This solves the problem such as the occurrence of uneven leveling that resultingly requires secondary processing, etc., thereby enabling the quality of products to be ensured and also saving human and material resources.SELECTED DRAWING: Figure 1

Description

The present invention relates to the field of stone pavement, and specifically is a quartz stone spreader device.

Artificial quartz is a new building decor material that is free of radioactive contamination, environmentally friendly and reusable, and is mainly composed of stones, unsaturated polyester resins, pigments, additives and granular powders. Many quartz stone manufacturers use quartz spreader devices to automatically spread the stone, but most quartz stone spreader devices now use a quartz stone spreader device to spread the stone directly from the container without an intermediate medium, which is not possible. It causes even spread and requires secondary treatment. Not only can this not guarantee the quality of the product, but it also wastes a large amount of human and material resources. The present invention can solve the above problems.

Chinese Patent Application Publication No. 1028622220

Technical problem:
Currently, most quartz stone spreader devices, when spreading stones, cause the stones to be spread directly from the container without an intermediate medium, causing uneven spreading, which requires a secondary treatment. Not only can we not guarantee the quality of our products, but we also waste a lot of human and material resources.

In order to solve the above problem, a quartz stone spreader device is designed, and the quartz stone spreader device according to the present invention includes an outer shell, and an operating space is installed in the outer shell, and the working space is above the working space. A T-shaped slide groove is formed on the inner wall, laterally moving parts are installed in the T-shaped slide groove, and the laterally moving parts are slidably connected to the T-shaped slide groove to the left and right. Lateral movement can be realized through movement, a support frame is installed at the lower end of the T-shaped slider, a right support plate is installed at the lower end of the support frame, and a stirring container is installed at the left end of the right support plate. A stirring space is installed in the stirring container, a motor is fitted in the T-shaped slider, a motor shaft is movably connected to the motor, and a stirring component is installed in the motor shaft. The stirring component is provided from a rotating rod installed at the lower end of the motor shaft, a stirring rod installed at the lower end of the rotating rod and symmetrically, and a stirring blade installed at the lower end of the stirring rod. The rotation of the rotating rod causes the stirring blade to move through the stirring rod, and the stirring blade stirs the mixed solid in the stirring space and pulls it out to the lower side of the stirring space. A hole is installed, the stirring space is communicated with the external space by a stone leveling hopper, a stone leveling part is installed on the right inner wall of the stone leveling hopper, and the stone leveling part is the above. The function of evenly dropping the stones in the stone leveling hopper and leveling the stones by the reciprocating movement of the stone leveling stopper plate slidably connected to the right wall of the stone leveling hopper to the left and right. A left support plate is installed at the outer end on the left side of the stirring space, a stone drop shaft is rotatably connected to the left support plate, and a stone drop component is installed on the stone drop shaft. The stone dropping part is composed of a stone dropping gear installed on the stone dropping shaft and a stone dropping rack slidably connected to the lower inner wall of the stirring space and slidably connected to the stone dropping gear. The rotation of the stone drop gear causes the stone drop rack to move left and right to realize a function of charging stone in the stirring space, and the stone drop shaft is located in front of the stone drop gear. One-way bearings are installed.

A driving wheel is installed on the motor shaft, a driven shaft is rotatably connected to the T-shaped slider, a driven wheel is installed on the driven shaft, and the driving wheel and the driven wheel are connected by a belt. A main umbrella gear is installed at the end of the lower end of the driven shaft, and a stone leveling area is installed on the rear inner wall of the operating space.

The laterally moving component further includes a disk shaft rotatably connected to the right support plate, the disk shaft is provided with an auxiliary bevel gear that meshes with the main bevel gear, and the rotation of the main bevel gear is said. Power is provided to the laterally moving parts, a disk is installed on the disk shaft, a protrusion point is installed on the disk, a fan-shaped gear located on the front side of the disk is installed on the disk shaft, and the right support is provided. A groove axle located below the disk shaft is rotatably connected to the plate, a groove wheel capable of contacting the fan-shaped gear is installed on the groove axle, and the groove wheel slides with the protrusion point. Six slide push grooves that are connectable and arranged in an annular shape are formed, and when the protrusion points and the slide push grooves are slidably connected, the groove wheel rotates 60 degrees and the groove axle. A lateral moving gear located on the rear side of the right support plate is installed in the right support plate, and a lateral moving rack that meshes with the lateral moving gear is installed on the rear inner wall of the operating space. The right support plate moves left and right.

The stone laying component further includes a rotating shaft rotatably connected to the right support plate and located on the rear side of the groove axle, and a secondary pulley is installed at the end of the front end of the rotating shaft. Since the main pulley is fixedly installed on the groove axle, the sub pulley and the main pulley are connected by a connecting belt, and the diameter of the main pulley is six times the diameter of the sub pulley, the main pulley is installed. When rotated 60 degrees, the auxiliary pulley rotates 360 degrees, and further, it is guaranteed that the rotating shaft rotates 360 degrees, and a rotating rod is installed on the rotating shaft, and the rotating rod is installed. A slide protrusion point is installed on the right support plate, a hinge connecting rod shaft located above the rotating shaft is rotatably connected to the right support plate, a hinge connecting rod is installed on the rotating shaft, and the hinge connecting rod is installed. A slide groove slidably connected to the slide protrusion point is formed in the inside, a link is connected to the hinge connecting rod by a hinge, and the link and the stone paving stop plate are connected by a hinge. ing.

The stone dropping component further includes a swing shaft rotatably connected to the right support plate, the swing shaft is provided with a swing rod capable of contacting the protrusion, and the right support plate is provided with a swing rod. A fixed block is installed, the fixed block and the swing rod are connected by a return spring, a swing gear located at the rear end of the right support plate is installed on the swing shaft, and the swing gear is installed on the right support plate. The turning shaft is rotatably connected to the turning shaft, a turning gear that meshes with the swing gear is installed on the turning shaft, and a pulley located behind the turning gear is installed on the turning shaft. The one-way bearing is connected by a stone drop belt, a suspension support frame is installed at the lower end of the stone drop rack, and the suspension support frame and the left end surface of the stone drop hopper are connected by a spring.

The one-way bearing further includes a bearing box rotatably connected to the stone drop shaft, a rotating space is installed in the bearing box, and the rotating space is fixed to the stone dropping shaft. A bearing wheel connected to the bearing wheel is installed, six selection teeth arranged in an annular shape are installed in the bearing wheel, the selection teeth and the bearing wheel are connected by a bearing spring, and the selection is made in the bearing wheel. A bearing block that can come into contact with the teeth is installed, and six thrust teeth arranged in an annular shape are installed on the inner wall of the rotating space.

The effect of the present invention is: Since the present invention uses a one-way bearing, some members do not move in the initial state, and by using a groove wheel, the stone laying work is divided into several steps. By doing so and using a stone leveling hopper, sufficient storage space is secured when dropping the stone, ensuring that the stone leveling work goes smoothly, and most quartz stone spreader devices are currently made of stone. When laying the stones, the stones are laid directly from the container without an intermediate medium, causing uneven laying, improving problems such as the need for secondary treatment, and ensuring product quality. , Can save human resources and material resources.

In order to explain the present invention in detail with reference to FIGS. 1 to 8 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 schematic diagram of the overall configuration of the present invention. FIG. 2 is a schematic configuration diagram in the AA direction in FIG. FIG. 3 is a schematic configuration diagram in the BB direction in FIG. FIG. 4 is an enlarged view of the configuration of part C in FIG. FIG. 5 is a schematic configuration diagram in the DD direction in FIG. FIG. 6 is a schematic configuration diagram in the EE direction in FIG. FIG. 7 is a schematic configuration diagram in the FF direction in FIG. FIG. 8 is a schematic configuration diagram of the unidirectional bearing in FIG.

The present invention relates to a quartz stone spreader device, and is mainly used for the work of laying out quartz stone, and will be further described below with reference to the drawings of the present invention.

The quartz stone spreader device according to the present invention includes an outer shell 11, an operating space 12 is installed in the outer shell 11, and a T-shaped slide groove 27 is formed on the upper inner wall of the operating space 12. A laterally moving component 901 is installed in the T-shaped slide groove 27, and the laterally moving component 901 laterally moves through the left and right movement of the T-shaped slider 21 slidably connected to the T-shaped slide groove 27. A support frame 71 is installed at the lower end of the T-shaped slider 21, a right support plate 38 is installed at the lower end of the support frame 71, and a stirring container 28 is installed at the left end of the right support plate 38. A stirring space 70 is installed in the stirring container 28, a motor 25 is fitted in the T-shaped slider 21, and a motor shaft 26 is movably connected to the motor 25. A stirring component 902 is installed in 26, and the stirring component 902 includes a rotating rod 29 installed at the lower end of the motor shaft 26 and a stirring rod 30 installed at the lower end of the rotating rod 29 and being symmetrical. The stirring blade 31 is composed of a stirring blade 31 installed at the lower end of the stirring rod 30, and the rotation of the rotating rod 29 causes the stirring blade 31 to move via the stirring rod 30, and the stirring blade 31 is further used in the stirring space. The mixed solid in 70 is agitated, a punch hole 72 is provided under the stirring space 70, and the stirring space 70 is communicated with an external space by a stone laying hopper 18 to level the stone. A stone leveling component 903 is installed on the inner wall on the right side of the hopper 18, and the stone leveling component 903 is a stone leveling plate 19 slidably connected to the right wall of the stone leveling hopper 18. By reciprocating to the left and right, the stone material in the stone material laying hopper 18 is evenly dropped to realize the function of laying the stone material, and the left support plate 73 is attached to the outer end on the left side of the stirring space 70. The stone dropping shaft 34 is rotatably connected to the left support plate 73, the stone dropping component 904 is installed on the stone dropping shaft 34, and the stone dropping component 904 is installed on the stone dropping shaft 34. The stone drop gear 33 is composed of the stone drop gear 33 and the stone drop rack 14 slidably connected to the lower inner wall of the stirring space 70 and slidably connected to the stone drop gear 33, and the rotation of the stone drop gear 33. As the stone material dropping rack 14 moves left and right, the stone material in the stirring space 70 is charged. The function is realized, and a one-way bearing 905 located on the front side of the stone drop gear 33 is installed on the stone drop shaft 34, and the one-way bearing 905 can change the rotation direction.

To be beneficial, a driving wheel 24 is installed on the motor shaft 26, a driven shaft 20 is rotatably connected to the T-shaped slider 21, and a driven wheel 22 is installed on the driven shaft 20. The wheel 24 and the driven wheel 22 are connected by a belt 23, a main umbrella gear 53 is installed at the end of the lower end of the driven shaft 20, and a stone leveling area 15 is provided on the rear inner wall of the working space 12. The stone material in the stone material leveling hopper 18 is installed and falls into the stone material leveling area 15, and the stone material leveling work is completed.

The laterally moving component 901 further includes a disk shaft 52 rotatably connected to the right support plate 38, and the disk shaft 52 is provided with an auxiliary gear 54 that meshes with the main gear 53. The rotation of the bevel gear 53 provides power to the laterally moving component 901, a disk 51 is installed on the disk shaft 52, a protrusion 50 is installed on the disk 51, and the disk 51 is installed on the disk shaft 52. A fan-shaped gear 35 located on the front side of the is installed, a groove axle 56 located below the disk shaft 52 is rotatably connected to the right support plate 38, and the groove axle 56 is connected to the fan-shaped gear 35. A groove wheel 49 that can be brought into contact with the groove wheel 49 is installed, and the groove wheel 49 is formed with six slide push grooves 48 that are slidably connected to the protrusion point 50 and arranged in an annular shape, and the protrusion point 50 and the slide are formed. When the push groove 48 is slidably connected, the groove wheel 49 rotates 60 degrees, and a lateral moving gear 55 located behind the right support plate 38 is installed on the groove axle 56. A lateral movement rack 13 that meshes with the lateral movement gear 55 is installed on the rear inner wall of the operating space 12, and the right support plate 38 moves left and right by the rotation of the lateral movement gear 55.

The stone laying component 903 further includes a rotating shaft 58 that is rotatably connected to the right support plate 38 and is located on the rear side of the groove axle 56, and a secondary pulley at the end of the front end of the rotating shaft 58. 44 is installed, a main pulley 46 is fixedly installed on the groove axle 56, the sub pulley 44 and the main pulley 46 are connected by a connecting belt 45, and the diameter of the main pulley 46 is the sub pulley 44. Since it is six times the diameter of the main pulley 46, when the main pulley 46 rotates 60 degrees, the sub pulley 44 rotates 360 degrees, and further, the rotation shaft 58 is guaranteed to rotate 360 degrees. A rotation rod 42 is installed on the rotation shaft 58, a slide protrusion point 41 is installed on the rotation rod 42, and a hinge connecting rod shaft 57 located above the rotation shaft 58 is installed on the right support plate 38. A hinge connecting rod 40 is installed on the rotating shaft 58, and a slide groove 74 slidably connected to the slide protrusion point 41 is formed in the hinge connecting rod 40. A link 43 is connected to the hinge connecting rod 40 by a hinge, the link 43 and the stone paving stopper plate 19 are connected by a hinge, the rotating rod 42 rotates 360 degrees, and the slide protrusion point. 41, the hinge connecting rod 40, and the link 43 are used to move the stone laying stop plate 19 to the right and return it to realize the work of laying the stone.

The stone dropping component 904 further includes a swing shaft 60 rotatably connected to the right support plate 38, and the swing shaft 60 is provided with a swing rod 39 capable of contacting the protrusion point 50. A fixing block 36 is installed on the right support plate 38, the fixing block 36 and the swing rod 39 are connected by a return spring 37, and the swing shaft 60 is located at the rear end of the right support plate 38. A swing gear 61 is installed, a turning shaft 59 is rotatably connected to the right support plate 38, and a turning gear 62 that meshes with the swing gear 61 is installed on the turning shaft 59. A pulley 75 located behind the turning gear 62 is installed in the 59, the pulley 75 and the one-way bearing 905 are connected by a stone dropping belt 32, and a suspension support frame is attached to the lower end of the stone dropping rack 14. 16 is installed, and the suspension support frame 16 and the left end surface of the stone drop hopper 18 are connected by a spring 17.

The one-way bearing 905 further includes a bearing box 65 rotatably connected to the stone drop shaft 34, a rotating space 66 is installed in the bearing box 65, and the rotating space 66 contains the above. A bearing wheel 63 fixedly connected to the stone drop shaft 34 is installed, six selective teeth 68 arranged in an annular shape are installed on the bearing wheel 63, and the selective teeth 68 and the bearing wheel 63 are bearings. A bearing block 64 connected by a spring 69 and capable of contacting the selected tooth 68 is installed on the bearing wheel 63, and six thrust teeth 67 arranged in an annular shape are installed on the inner wall of the rotating space 66. The thrust tooth 67 and the select tooth 68 can come into contact with each other, the select tooth 68 and the bearing block 64 come into contact with each other, the select tooth 68 and the thrust tooth 67 come into contact with each other, and the select tooth 68 and the bearing block come into contact with each other. The contact state with 64 is different from the contact state between the selected tooth 68 and the thrust tooth 67.

Hereinafter, the procedure for using the present invention will be described in detail with reference to FIGS. 1 to 8.

In the initial state, the swing rod 39 is in a horizontal state, and the stone leveling stopper plate 19 extends to the stone leveling hopper 18 to block the upper part and the lower part of the stone leveling hopper 18 to remove the stone material. Since the rack 14 and the punch hole 72 are hermetically connected to each other, the stirring space 70 and the external space are not communicated with each other, and the T-shaped slider 21 is located on the far right.

When the stone material is put into the stirring space 70 at a constant ratio, the motor 25 is started to rotate the motor shaft 26, and the motor shaft 26 is symmetrical via the stirring rod 30 which is symmetrical with the rotating rod 29. The stirring blade 31 is driven, and the mixed stone material in the stirring space 70 is stirred by the stirring blade 31 to realize the stirring function. At this time, the driven shaft 20 is sequentially the hinge connecting rod shaft 57, the belt 23, and the slave. It is driven by the driving wheel 22 to rotate, and the rotation of the driven shaft 20 causes the protrusion point 50 to rotate clockwise via the main umbrella gear 53, the auxiliary umbrella gear 54, the disk shaft 52, and the disk 51, and swings with the protrusion point 50. In the process of contacting the moving rod 39 and swinging the swing rod 39, the return spring 37 accumulates an elastic recovery force, and in this order, the pulley 75 is rotated clockwise via the swing shaft 60, the swing gear 61, and the turning gear 62. The stone drop gear 33 is rotated clockwise via the stone drop belt 32, the stone leveling part 903, and the stone drop shaft 34 in this order, and the stone drop gear 33 rotates clockwise. The stone dropping rack 14 moves to the left to stir the stone in the stirring space 70 and drop it into the stone laying leveling hopper 18, and the stone laying stopper plate 19 stops the falling of the stone, and in this process. , The spring 17 stores the elastic recovery force, and when the protrusion point 50 and the swing rod 39 do not come into contact with each other, the return spring 37 releases the elastic recovery force to return the swing rod 39 to the horizontal state, and at the same time, the spring. 17 releases an elastic recovery force, the stone dropping rack 14 is driven by the suspension support frame 16 to return, and when the protrusion point 50 and the slide push groove 48 are slidably connected, the protrusion point 50 is a slide push groove. The groove wheel 49 is rotated 60 degrees counterclockwise via 48, and the rotation of the groove wheel 49 rotates the lateral moving gear 55 counterclockwise via the groove axle 56, and the lateral moving gear 55 and the lateral moving rack. Since the 13 meshes with each other, the right support plate 38, the stirring container 28, and the stone leveling hopper 18 move to the left, and in this process, the groove wheel 49 moves the groove axle 56, the main pulley 46, and the connecting belt 45 in this order. The auxiliary pulley 44 is rotated counterclockwise 360 degrees via the auxiliary pulley 44, and at the same time, the auxiliary pulley 44 sequentially rotates the rotating shaft 58, the rotating rod 42, the slide protrusion point 41, the slide groove 74, the hinge connecting rod 40, and the link. The stone leveling stop plate 19 is moved to the right via 43, and the stone material in the stone leveling hopper 18 falls evenly into the stone leveling area 15, the stone leveling work is completed, and the auxiliary pulley 4 With the rotation of 4, the auxiliary pulley 44 moves the stone paving stopper plate 19 to the left via the rotating shaft 58, the rotating rod 42, the slide protrusion point 41, the slide groove 74, the hinge connecting rod 40, and the link 43 in order. After all the work of laying out the stones is completed, the motor 25 is reversed, and when the quartz stone spreader device of the present invention returns to the initial state, the motor 25 is stopped.

By the above method, those skilled in the art can make various modifications based on the working conditions within the scope of the present invention.

The present invention relates to the field of stone pavement, and specifically is a quartz stone spreader device.

Artificial quartz is a new building decor material that is free of radioactive contamination, environmentally friendly and reusable, and is mainly composed of stones, unsaturated polyester resins, pigments, additives and granular powders. Many quartz stone manufacturers use quartz spreader devices to automatically spread the stone, but most quartz stone spreader devices now use a quartz stone spreader device to spread the stone directly from the container without an intermediate medium, which is not possible. It causes even spread and requires secondary treatment. Not only can this not guarantee the quality of the product, but it also wastes a large amount of human and material resources. The present invention can solve the above problems.

Chinese Patent Application Publication No. 1028622220

Technical problem: Currently, most quartz stone spreader devices, when leveling stones, cause the stones to be spread directly from the container without an intermediate medium, causing uneven spreading and requiring secondary treatment. Not only can this not guarantee the quality of the product, but it also wastes a large amount of human and material resources.

In order to solve the above problem, a quartz stone spreader device is designed, and the quartz stone spreader device according to the present invention includes an outer shell, and an operating space is installed in the outer shell, and the working space is above the working space. A T-shaped slide groove is formed on the inner wall, laterally moving parts are installed in the T-shaped slide groove, and the laterally moving parts are slidably connected to the T-shaped slide groove to the left and right. Lateral movement can be realized through movement, a support frame is installed at the lower end of the T-shaped slider, a right support plate is installed at the lower end of the support frame, and a stirring container is installed at the left end of the right support plate. A stirring space is installed in the stirring container, a motor is fitted in the T-shaped slider, a motor shaft is movably connected to the motor, and a stirring component is installed in the motor shaft. The stirring component is provided from a rotating rod installed at the lower end of the motor shaft, a stirring rod installed at the lower end of the rotating rod and symmetrically, and a stirring blade installed at the lower end of the stirring rod. The rotation of the rotating rod causes the stirring blade to move through the stirring rod, and the stirring blade stirs the mixed solid in the stirring space and pulls it out to the lower side of the stirring space. A hole is installed, the stirring space is communicated with the external space by a stone leveling hopper, a stone leveling part is installed on the right inner wall of the stone leveling hopper, and the stone leveling part is the above. The function of evenly dropping the stones in the stone leveling hopper and leveling the stones by the reciprocating movement of the stone leveling stopper plate slidably connected to the right wall of the stone leveling hopper to the left and right. A left support plate is installed at the outer end on the left side of the stirring space, a stone drop shaft is rotatably connected to the left support plate, and a stone drop component is installed on the stone drop shaft. The stone dropping part is composed of a stone dropping gear installed on the stone dropping shaft and a stone dropping rack slidably connected to the lower inner wall of the stirring space and slidably connected to the stone dropping gear. The rotation of the stone drop gear causes the stone drop rack to move left and right to realize a function of charging stone in the stirring space, and the stone drop shaft is located in front of the stone drop gear. One-way bearings are installed.

A driving wheel is installed on the motor shaft, a driven shaft is rotatably connected to the T-shaped slider, a driven wheel is installed on the driven shaft, and the driving wheel and the driven wheel are connected by a belt. A main umbrella gear is installed at the end of the lower end of the driven shaft, and a stone leveling area is installed on the rear inner wall of the operating space.

The laterally moving component further includes a disk shaft rotatably connected to the right support plate, the disk shaft is provided with an auxiliary bevel gear that meshes with the main bevel gear, and the rotation of the main bevel gear is said. Power is provided to the laterally moving parts, a disk is installed on the disk shaft, a protrusion point is installed on the disk, a fan-shaped gear located on the front side of the disk is installed on the disk shaft, and the right support is provided. A groove axle located below the disk shaft is rotatably connected to the plate, a groove wheel capable of contacting the fan-shaped gear is installed on the groove axle, and the groove wheel slides with the protrusion point. Six slide push grooves that are connectable and arranged in an annular shape are formed, and when the protrusion points and the slide push grooves are slidably connected, the groove wheel rotates 60 degrees and the groove axle. A lateral moving gear located on the rear side of the right support plate is installed in the right support plate, and a lateral moving rack that meshes with the lateral moving gear is installed on the rear inner wall of the operating space. The right support plate moves left and right.

The stone laying component further includes a rotating shaft rotatably connected to the right support plate and located on the rear side of the groove axle, and a secondary pulley is installed at the end of the front end of the rotating shaft. Since the main pulley is fixedly installed on the groove axle, the sub pulley and the main pulley are connected by a connecting belt, and the diameter of the main pulley is six times the diameter of the sub pulley, the main pulley is installed. When rotated 60 degrees, the auxiliary pulley rotates 360 degrees, and further, it is guaranteed that the rotating shaft rotates 360 degrees, and a rotating rod is installed on the rotating shaft, and the rotating rod is installed. A slide protrusion point is installed on the right support plate, a hinge connecting rod shaft located above the rotating shaft is rotatably connected to the right support plate, a hinge connecting rod is installed on the rotating shaft, and the hinge connecting rod is installed. A slide groove slidably connected to the slide protrusion point is formed in the inside, a link is connected to the hinge connecting rod by a hinge, and the link and the stone paving stop plate are connected by a hinge. ing.

The stone dropping component further includes a swing shaft rotatably connected to the right support plate, the swing shaft is provided with a swing rod capable of contacting the protrusion, and the right support plate is provided with a swing rod. A fixed block is installed, the fixed block and the swing rod are connected by a return spring, a swing gear located at the rear end of the right support plate is installed on the swing shaft, and the swing gear is installed on the right support plate. The turning shaft is rotatably connected to the turning shaft, a turning gear that meshes with the swing gear is installed on the turning shaft, and a pulley located behind the turning gear is installed on the turning shaft. The one-way bearing is connected by a stone drop belt, a suspension support frame is installed at the lower end of the stone drop rack, and the suspension support frame and the left end surface of the stone drop hopper are connected by a spring.

The one-way bearing further includes a bearing box rotatably connected to the stone drop shaft, a rotating space is installed in the bearing box, and the rotating space is fixed to the stone dropping shaft. A bearing wheel connected to the bearing wheel is installed, six selection teeth arranged in an annular shape are installed in the bearing wheel, the selection teeth and the bearing wheel are connected by a bearing spring, and the selection is made in the bearing wheel. A bearing block that can come into contact with the teeth is installed, and six thrust teeth arranged in an annular shape are installed on the inner wall of the rotating space.

The effect of the present invention is: Since the present invention uses a one-way bearing, some members do not move in the initial state, and by using a groove wheel, the stone laying work is divided into several steps. By doing so and using a stone leveling hopper, sufficient storage space is secured when dropping the stone, ensuring that the stone leveling work goes smoothly, and most quartz stone spreader devices are currently made of stone. When laying the stones, the stones are laid directly from the container without an intermediate medium, causing uneven laying, improving problems such as the need for secondary treatment, and ensuring product quality. , Can save human resources and material resources.

In order to explain the present invention in detail with reference to FIGS. 1 to 8 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 schematic diagram of the overall configuration of the present invention. FIG. 2 is a schematic configuration diagram in the AA direction in FIG. FIG. 3 is a schematic configuration diagram in the BB direction in FIG. FIG. 4 is an enlarged view of the configuration of part C in FIG. FIG. 5 is a schematic configuration diagram in the DD direction in FIG. FIG. 6 is a schematic configuration diagram in the EE direction in FIG. FIG. 7 is a schematic configuration diagram in the FF direction in FIG. FIG. 8 is a schematic configuration diagram of the unidirectional bearing in FIG.

The present invention relates to a quartz stone spreader device, and is mainly used for the work of laying out quartz stone, and will be further described below with reference to the drawings of the present invention.

The quartz stone spreader device according to the present invention includes an outer shell 11, an operating space 12 is installed in the outer shell 11, and a T-shaped slide groove 27 is formed on the upper inner wall of the operating space 12. A laterally moving component 901 is installed in the T-shaped slide groove 27, and the laterally moving component 901 laterally moves through the left and right movement of the T-shaped slider 21 slidably connected to the T-shaped slide groove 27. A support frame 71 is installed at the lower end of the T-shaped slider 21, a right support plate 38 is installed at the lower end of the support frame 71, and a stirring container 28 is installed at the left end of the right support plate 38. A stirring space 70 is installed in the stirring container 28, a motor 25 is fitted in the T-shaped slider 21, and a motor shaft 26 is movably connected to the motor 25. A stirring component 902 is installed in 26, and the stirring component 902 includes a rotating rod 29 installed at the lower end of the motor shaft 26 and a stirring rod 30 installed at the lower end of the rotating rod 29 and being symmetrical. The stirring blade 31 is composed of a stirring blade 31 installed at the lower end of the stirring rod 30, and the rotation of the rotating rod 29 causes the stirring blade 31 to move via the stirring rod 30, and the stirring blade 31 is further used in the stirring space. The mixed solid in 70 is agitated, a punch hole 72 is provided under the stirring space 70, and the stirring space 70 is communicated with an external space by a stone laying hopper 18 to level the stone. A stone leveling component 903 is installed on the inner wall on the right side of the hopper 18, and the stone leveling component 903 is a stone leveling plate 19 slidably connected to the right wall of the stone leveling hopper 18. By reciprocating to the left and right, the stone material in the stone material laying hopper 18 is evenly dropped to realize the function of laying the stone material, and the left support plate 73 is attached to the left outer end of the stirring space 70. The stone dropping shaft 34 is rotatably connected to the left support plate 73, the stone dropping component 904 is installed on the stone dropping shaft 34, and the stone dropping component 904 is installed on the stone dropping shaft 34. The stone drop gear 33 is composed of the stone drop gear 33 and the stone drop rack 14 slidably connected to the lower inner wall of the stirring space 70 and slidably connected to the stone drop gear 33, and the rotation of the stone drop gear 33. As the stone material dropping rack 14 moves left and right, the stone material in the stirring space 70 is charged. The function is realized, and the one-way bearing 905 located on the front side of the stone drop gear 33 is installed on the stone drop shaft 34, and the one-way bearing 905 can be realized to rotate in one direction .

To be beneficial, a driving wheel 24 is installed on the motor shaft 26, a driven shaft 20 is rotatably connected to the T-shaped slider 21, and a driven wheel 22 is installed on the driven shaft 20. The wheel 24 and the driven wheel 22 are connected by a belt 23, a main umbrella gear 53 is installed at the end of the lower end of the driven shaft 20, and a stone leveling area 15 is provided on the rear inner wall of the working space 12. The stone material in the stone material leveling hopper 18 is installed and falls into the stone material leveling area 15, and the stone material leveling work is completed.

The laterally moving component 901 further includes a disk shaft 52 rotatably connected to the right support plate 38, and the disk shaft 52 is provided with an auxiliary gear 54 that meshes with the main gear 53. The rotation of the bevel gear 53 provides power to the laterally moving component 901, a disk 51 is installed on the disk shaft 52, a protrusion 50 is installed on the disk 51, and the disk 51 is installed on the disk shaft 52. A fan-shaped gear 35 located on the front side of the is installed, a groove axle 56 located below the disk shaft 52 is rotatably connected to the right support plate 38, and the groove axle 56 is connected to the fan-shaped gear 35. A groove wheel 49 that can be brought into contact with the groove wheel 49 is installed, and the groove wheel 49 is formed with six slide push grooves 48 that are slidably connected to the protrusion point 50 and arranged in an annular shape, and the protrusion point 50 and the slide are formed. When the push groove 48 is slidably connected, the groove wheel 49 rotates 60 degrees, and a lateral moving gear 55 located behind the right support plate 38 is installed on the groove axle 56. A lateral movement rack 13 that meshes with the lateral movement gear 55 is installed on the rear inner wall of the operating space 12, and the right support plate 38 moves left and right by the rotation of the lateral movement gear 55.

The stone laying component 903 further includes a rotating shaft 58 that is rotatably connected to the right support plate 38 and is located on the rear side of the groove axle 56, and a secondary pulley at the end of the front end of the rotating shaft 58. 44 is installed, a main pulley 46 is fixedly installed on the groove axle 56, the sub pulley 44 and the main pulley 46 are connected by a connecting belt 45, and the diameter of the main pulley 46 is the sub pulley 44. Since it is six times the diameter of the main pulley 46, when the main pulley 46 rotates 60 degrees, the sub pulley 44 rotates 360 degrees, and further, the rotation shaft 58 is guaranteed to rotate 360 degrees. A rotation rod 42 is installed on the rotation shaft 58, a slide protrusion point 41 is installed on the rotation rod 42, and a hinge connecting rod shaft 57 located above the rotation shaft 58 is installed on the right support plate 38. A hinge connecting rod 40 is installed on the rotating shaft 58, and a slide groove 74 slidably connected to the slide protrusion point 41 is formed in the hinge connecting rod 40. A link 43 is connected to the hinge connecting rod 40 by a hinge, the link 43 and the stone paving stopper plate 19 are connected by a hinge, the rotating rod 42 rotates 360 degrees, and the slide protrusion point. 41, the hinge connecting rod 40, and the link 43 are used to move the stone laying stop plate 19 to the right and return it to realize the work of laying the stone.

The stone dropping component 904 further includes a swing shaft 60 rotatably connected to the right support plate 38, and the swing shaft 60 is provided with a swing rod 39 capable of contacting the protrusion point 50. A fixing block 36 is installed on the right support plate 38, the fixing block 36 and the swing rod 39 are connected by a return spring 37, and the swing shaft 60 is located at the rear end of the right support plate 38. A swing gear 61 is installed, a turning shaft 59 is rotatably connected to the right support plate 38, and a turning gear 62 that meshes with the swing gear 61 is installed on the turning shaft 59. A pulley 75 located behind the turning gear 62 is installed in the 59, the pulley 75 and the one-way bearing 905 are connected by a stone dropping belt 32, and a suspension support frame is attached to the lower end of the stone dropping rack 14. 16 is installed, and the suspension support frame 16 and the left end surface of the stone drop hopper 18 are connected by a spring 17.

The one-way bearing 905 further includes a bearing box 65 rotatably connected to the stone drop shaft 34, a rotating space 66 is installed in the bearing box 65, and the rotating space 66 contains the above. A bearing wheel 63 fixedly connected to the stone drop shaft 34 is installed, six selective teeth 68 arranged in an annular shape are installed on the bearing wheel 63, and the selective teeth 68 and the bearing wheel 63 are bearings. A bearing block 64 connected by a spring 69 and capable of contacting the selected tooth 68 is installed on the bearing wheel 63, and six thrust teeth 67 arranged in an annular shape are installed on the inner wall of the rotating space 66. The thrust tooth 67 and the select tooth 68 can come into contact with each other, the select tooth 68 and the bearing block 64 come into contact with each other, the select tooth 68 and the thrust tooth 67 come into contact with each other, and the select tooth 68 and the bearing block come into contact with each other. The contact state with 64 is different from the contact state between the selected tooth 68 and the thrust tooth 67.

Hereinafter, the procedure for using the present invention will be described in detail with reference to FIGS. 1 to 8.

In the initial state, the swing rod 39 is in a horizontal state, and the stone leveling stopper plate 19 extends to the stone leveling hopper 18 to block the upper part and the lower part of the stone leveling hopper 18 to remove the stone material. Since the rack 14 and the punch hole 72 are hermetically connected to each other, the stirring space 70 and the external space are not communicated with each other, and the T-shaped slider 21 is located on the far right.

When the stone material is put into the stirring space 70 at a constant ratio, the motor 25 is started to rotate the motor shaft 26, and the motor shaft 26 is symmetrical via the stirring rod 30 which is symmetrical with the rotating rod 29. The stirring blade 31 is driven, and the mixed stone material in the stirring space 70 is stirred by the stirring blade 31 to realize the stirring function. At this time, the driven shaft 20 is sequentially the hinge connecting rod shaft 57, the belt 23, and the slave. It is driven by the driving wheel 22 to rotate, and the rotation of the driven shaft 20 causes the protrusion point 50 to rotate clockwise via the main umbrella gear 53, the auxiliary umbrella gear 54, the disk shaft 52, and the disk 51, and swings with the protrusion point 50. In the process of contacting the moving rod 39 and swinging the swing rod 39, the return spring 37 accumulates an elastic recovery force, and in this order, the pulley 75 is rotated clockwise via the swing shaft 60, the swing gear 61, and the turning gear 62. The stone drop gear 33 is rotated clockwise via the stone drop belt 32, the stone leveling part 903, and the stone drop shaft 34 in this order, and the stone drop gear 33 rotates clockwise. The stone dropping rack 14 moves to the left to stir the stone in the stirring space 70 and drop it into the stone laying leveling hopper 18, and the stone laying stopper plate 19 stops the falling of the stone, and in this process. , The spring 17 stores the elastic recovery force, and when the protrusion point 50 and the swing rod 39 do not come into contact with each other, the return spring 37 releases the elastic recovery force to return the swing rod 39 to the horizontal state, and at the same time, the spring. 17 releases an elastic recovery force, the stone dropping rack 14 is driven by the suspension support frame 16 to return, and when the protrusion point 50 and the slide push groove 48 are slidably connected, the protrusion point 50 is a slide push groove. The groove wheel 49 is rotated 60 degrees counterclockwise via 48, and the rotation of the groove wheel 49 rotates the lateral moving gear 55 counterclockwise via the groove axle 56, and the lateral moving gear 55 and the lateral moving rack. Since the 13 meshes with each other, the right support plate 38, the stirring container 28, and the stone leveling hopper 18 move to the left, and in this process, the groove wheel 49 moves the groove axle 56, the main pulley 46, and the connecting belt 45 in this order. The auxiliary pulley 44 is rotated counterclockwise 360 degrees via the auxiliary pulley 44, and at the same time, the auxiliary pulley 44 sequentially rotates the rotating shaft 58, the rotating rod 42, the slide protrusion point 41, the slide groove 74, the hinge connecting rod 40, and the link. The stone leveling stop plate 19 is moved to the right via 43, and the stone material in the stone leveling hopper 18 falls evenly into the stone leveling area 15, the stone leveling work is completed, and the auxiliary pulley 4 With the rotation of 4, the auxiliary pulley 44 moves the stone paving stopper plate 19 to the left via the rotating shaft 58, the rotating rod 42, the slide protrusion point 41, the slide groove 74, the hinge connecting rod 40, and the link 43 in order. After all the work of laying out the stones is completed, the motor 25 is reversed, and when the quartz stone spreader device of the present invention returns to the initial state, the motor 25 is stopped.

By the above method, those skilled in the art can make various modifications based on the working conditions within the scope of the present invention.

Claims (6)

A working space is installed in the outer shell including the outer shell, a T-shaped slide groove is formed on the upper inner wall of the working space, and a laterally moving component is installed in the T-shaped slide groove. The moving component can be laterally moved through the left and right movement of the T-shaped slider slidably connected to the T-shaped slide groove, and a support frame is installed at the lower end of the T-shaped slider, and the support frame is provided. A right support plate is installed at the lower end of the right support plate, a stirring container is installed at the left end of the right support plate, a stirring space is installed in the stirring container, and a motor is fitted in the T-shaped slider. , The motor shaft is connected to the motor so that it can be transmitted.
A stirring component is installed on the motor shaft, and the stirring component includes a rotating rod installed at the lower end of the motor shaft, a stirring rod installed at the lower end of the rotating rod and symmetrical, and the stirring rod. It is composed of a stirring blade installed at the lower end of the stirring blade, the rotation of the rotating rod causes the stirring blade to move through the stirring rod, and the stirring blade further stirs the mixed solid in the stirring space. A punch hole is installed under the stirring space, and the stirring space is communicated with the external space by a stone laying leveling hopper.
A stone leveling part is installed on the right inner wall of the stone leveling hopper, and the stone leveling part is a stone leveling stopper plate slidably connected to the right wall of the stone leveling hopper. By reciprocating to the left and right, the stones in the stone laying hopper are evenly dropped to realize the function of laying the stones, and a left support plate is installed at the outer end on the left side of the stirring space. A stone dropping shaft is rotatably connected to the left support plate, a stone dropping component is installed on the stone dropping shaft, and the stone dropping component is agitated with a stone dropping gear installed on the stone dropping shaft. It is composed of a stone dropping rack that is slidably connected to the lower inner wall of the space and slidably connected to the stone dropping gear, and the stone dropping rack moves left and right by the rotation of the stone dropping gear. A quartz stone spreader device that realizes a function of charging stones in a stirring space and is characterized in that a one-way bearing located on the front side of the stone drop gear is installed on the stone drop shaft. A driving wheel is installed on the motor shaft, a driven shaft is rotatably connected to the T-shaped slider, a driven wheel is installed on the driven shaft, and the driving wheel and the driven wheel are connected by a belt. The quartz stone spreader according to claim 1, wherein a main umbrella gear is installed at the end of the lower end of the driven shaft, and a stone leveling area is installed on the rear inner wall of the operating space. apparatus. The laterally moving component further includes a disk shaft rotatably connected to the right support plate, the disk shaft is provided with an auxiliary bevel gear that meshes with the main bevel gear, and the rotation of the main bevel gear is said. Power is provided to the laterally moving parts, a disk is installed on the disk shaft, a protrusion point is installed on the disk, a fan-shaped gear located on the front side of the disk is installed on the disk shaft, and the right support is provided. A groove axle located below the disk shaft is rotatably connected to the plate, a groove wheel capable of contacting the fan-shaped gear is installed on the groove axle, and the groove wheel slides with the protrusion point. Six slide push grooves that are connectable and arranged in an annular shape are formed, and when the protrusion points and the slide push grooves are slidably connected, the groove wheel rotates 60 degrees and the groove axle. A lateral moving gear located on the rear side of the right support plate is installed in the right support plate, and a lateral moving rack that meshes with the lateral moving gear is installed on the rear inner wall of the operating space. The quartz stone spreader device according to claim 1, wherein the right support plate moves left and right. The stone laying component further includes a rotating shaft rotatably connected to the right support plate and located on the rear side of the groove axle, and a secondary pulley is installed at the end of the front end of the rotating shaft. Since the main pulley is fixedly installed on the groove axle, the sub pulley and the main pulley are connected by a connecting belt, and the diameter of the main pulley is six times the diameter of the sub pulley, the main pulley is installed. When rotated 60 degrees, the auxiliary pulley rotates 360 degrees, and further, it is guaranteed that the rotating shaft rotates 360 degrees, and a rotating rod is installed on the rotating shaft, and the rotating rod is installed. A slide protrusion point is installed on the right support plate, a hinge connecting rod shaft located above the rotating shaft is rotatably connected to the right support plate, a hinge connecting rod is installed on the rotating shaft, and the hinge connecting rod is installed. A slide groove slidably connected to the slide protrusion point is formed in the inside, a link is connected to the hinge connecting rod by a hinge, and the link and the stone paving stop plate are connected by a hinge. The quartz stone spreader device according to claim 1, wherein the device is characterized by the above. The stone dropping component further includes a swing shaft rotatably connected to the right support plate, the swing shaft is provided with a swing rod capable of contacting the protrusion, and the right support plate is provided with a swing rod. A fixed block is installed, the fixed block and the swing rod are connected by a return spring, a swing gear located at the rear end of the right support plate is installed on the swing shaft, and the swing gear is installed on the right support plate. The turning shaft is rotatably connected to the turning shaft, a turning gear that meshes with the swing gear is installed on the turning shaft, and a pulley located behind the turning gear is installed on the turning shaft. The one-way bearing is connected by a stone drop belt, a suspension support frame is installed at the lower end of the stone drop rack, and the suspension support frame and the left end surface of the stone drop hopper are connected by a spring. The quartz stone spreader apparatus according to claim 1. The one-way bearing further includes a bearing box rotatably connected to the stone drop shaft, a rotating space is installed in the bearing box, and the rotating space is fixed to the stone dropping shaft. A bearing wheel connected to the bearing wheel is installed, six selection teeth arranged in an annular shape are installed in the bearing wheel, the selection teeth and the bearing wheel are connected by a bearing spring, and the selection is made in the bearing wheel. The quartz stone spreader device according to claim 1, wherein a bearing block capable of contacting the teeth is installed, and six thrust teeth arranged in an annular shape are installed on the inner wall of the rotating space.

Images