Disclosure of Invention
The technical problem is as follows:
when most quartz stone panel material distributing machine cloth at present, the material is directly unrestrained from the container, does not have middle medium, and the cloth is inhomogeneous can appear, needs the condition of secondary treatment, so not only can not ensure the quality of product, can waste a large amount of manpower, material resources moreover.
In order to solve the problems, the embodiment designs a quartz stone plate material distribution device, which comprises a shell, wherein a working cavity is arranged in the shell, a T-shaped chute is arranged on the inner wall of the upper side of the working cavity, a transverse moving component is arranged on the T-shaped chute, the transverse moving component comprises a T-shaped slide block which is connected to the T-shaped chute in a sliding manner, a support frame is arranged at the lower end of the T-shaped slide block, a right support plate is arranged at the lower end of the support frame, a stirring container is arranged at the left end of the right support plate, a stirring cavity is arranged in the stirring container, a motor is embedded in the T-shaped slide block, the motor is connected with a motor shaft in a power mode, a stirring component is arranged on the motor shaft, the stirring component comprises a rotating rod arranged at the lower end of the, the stirring cavity is communicated with the outside and is connected with a distribution funnel, the inner wall of the right side of the distribution funnel is provided with a distribution assembly, and the distribution assembly can make materials in the distribution funnel fall uniformly through the left-right reciprocating motion of a distribution baffle plate which is connected to the right wall of the distribution funnel in a sliding mode, so that the distribution function is realized; stirring chamber left side outer end is equipped with left extension board, it is connected with the blowing axle to rotate on the extension board of a left side, the epaxial blowing subassembly that is equipped with of blowing, the blowing subassembly including set up in epaxial blowing gear of blowing, sliding connection in stir chamber downside inner wall and with blowing gear sliding connection's blowing rack, the epaxial one-way bearing that is located of blowing gear front side that is equipped with of blowing.
Preferably, a driving wheel is arranged on the motor shaft, a driven shaft is connected to the T-shaped sliding block in a rotating mode, a driven wheel is arranged on the driven shaft, a belt is connected between the driving wheel and the driven wheel, a main bevel gear is arranged at the tail end of the lower end of the driven shaft, and a cloth area is arranged on the inner wall of the rear side of the working cavity.
Wherein, the transverse moving component also comprises a disk shaft which is rotationally connected with the right support plate, an auxiliary bevel gear which is meshed with the main bevel gear is arranged on the disk shaft, the rotation of the main bevel gear provides the power of the transverse moving component, a disk is arranged on the disk shaft, a salient point is arranged on the disk, a sector gear which is arranged at the front side of the disk is arranged on the disk shaft, a slotted disk shaft which is arranged at the lower side of the disk shaft is rotationally connected with the right support plate, a slotted disk which can be abutted against the sector gear and a main belt wheel which is arranged at the front side of the slotted disk are arranged on the slotted disk, six sliding push grooves which are connected with the salient point in a sliding way and distributed in an annular array are arranged on the slotted disk, when the salient point is connected with the sliding push grooves in a sliding way, the slotted disk rotates sixty degrees, a transverse moving gear which is arranged at the rear, and a transverse moving rack meshed and connected with the transverse moving gear is arranged on the inner wall of the rear side of the working cavity, and the rotation of the transverse moving gear drives the right support plate to move left and right.
The cloth component further comprises a turnover shaft which is rotatably connected with the right support plate and located on the rear side of the fluted disc shaft, an auxiliary belt wheel is arranged at the tail end of the front end of the turnover shaft, a material discharging belt is connected between the auxiliary belt wheel and the main belt wheel, the diameter of the main belt wheel is six times of that of the auxiliary belt wheel, the auxiliary belt wheel rotates for a circle when the main belt wheel rotates for sixty degrees, the turnover rod rotates for a circle, the turnover shaft is provided with the turnover rod, the turnover rod is provided with sliding bumps, the right support plate is rotatably connected with a hinge rod shaft located on the upper side of the turnover shaft, the hinge rod shaft is provided with a hinge rod, a sliding groove capable of being slidably connected with the sliding bumps is formed in the hinge rod, and the hinge rod is hinged to the cloth baffle.
The discharging assembly further comprises a swinging shaft connected with the right support plate in a rotating mode, a swinging rod abutted with the salient points is arranged on the swinging shaft, a fixed block is arranged on the right support plate, a reset spring is connected between the fixed block and the swinging rod, a swinging gear located at the rear end of the right support plate is arranged on the swinging shaft, a reversing shaft is connected to the right support plate in a rotating mode, a reversing gear connected with the swinging gear in a meshed mode is arranged on the reversing shaft, a belt pulley located on the rear side of the reversing gear is arranged on the reversing shaft, a discharging belt is connected between the belt pulley and the one-way bearing, a hanging support is arranged at the lower end of a discharging rack, and the hanging support is connected with a spring on the left end face of the distributing.
Wherein, one-way bearing still include with the blowing axle rotates the bearing box of connecting, be equipped with in the bearing box and rotate the chamber, rotate the intracavity be equipped with blowing axle fixed connection's bearing wheel, be equipped with six selection teeth that annular array distributes on the bearing wheel, select the tooth with be connected with the bearing spring between the bearing wheel, be equipped with on the bearing wheel can with select the bearing block of tooth butt, rotate intracavity wall on be equipped with can with select six thrust tooth that tooth butt and annular array distribute.
The invention has the beneficial effects that: the invention adopts the one-way bearing, ensures that partial components do not move when the device is in the initial state, adopts the grooved pulley to ensure that the material distribution process is carried out step by step, adopts the material distribution hopper to ensure that the material has a storage space during each material discharge, ensures the material distribution work, and improves the conditions that the material directly falls from the container, has no intermediate medium, can have uneven material distribution and needs secondary treatment when most of the prior quartz stone plate material distributor distributes materials, thus not only the product quality can not be ensured, but also the current situations of large amount of manpower and material resources can be wasted.Drawings
For ease of illustration, the invention is described in detail by the following specific examples and figures.
FIG. 1 is a schematic view of the overall structure of a quartz stone plate distribution device according to the present invention;
FIG. 2 is a schematic view of the structure in the direction "A-A" of FIG. 1;
FIG. 3 is a schematic view of the structure in the direction "B-B" of FIG. 1;
FIG. 4 is a schematic enlarged view of the structure of "C" of FIG. 1;
FIG. 5 is a schematic view of the structure in the direction "D-D" of FIG. 4;
FIG. 6 is a schematic view of the structure in the direction "E-E" of FIG. 4;
FIG. 7 is a schematic view of the structure in the direction "F-F" of FIG. 4;
fig. 8 is a schematic structural view of the one-way bearing of fig. 1.
Detailed Description
The invention will now be described in detail with reference to fig. 1-8, for ease of description, the orientations described below will now be defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.
The invention relates to a quartz stone plate material distribution device, which is mainly applied to the plate material distribution process, and the invention is further explained by combining the attached drawings of the invention as follows:
the quartz stone plate distributing device comprises a shell 11, a working cavity 12 is arranged in the shell 11, a T-shaped chute 27 is arranged on the inner wall of the upper side of the working cavity 12, a transverse moving component 901 is arranged on the T-shaped chute 27, the transverse moving component 901 can move left and right through a T-shaped slide block 21 connected to the T-shaped chute 27 in a sliding mode to realize a transverse moving function, a support frame 71 is arranged at the lower end of the T-shaped slide block 21, a right support plate 38 is arranged at the lower end of the support frame 71, a stirring container 28 is arranged at the left end of the right support plate 38, a stirring cavity 70 is arranged in the stirring container 28, a motor 25 is embedded in the T-shaped slide block 21, the motor 25 is in power connection with a motor shaft 26, a stirring component 902 is arranged on the motor shaft 26, the stirring component 902 comprises a rotating rod 29 arranged at the lower, the stirring blade 31 is arranged at the lower end of the stirring rod 30, the rotation of the rotating rod 29 drives the stirring blade 31 to move through the stirring rod 30, the mixed solid in the stirring cavity 70 is stirred, the lower side of the stirring cavity 70 is provided with a through hole 72, the stirring cavity 70 is communicated with the outside and is connected with the distribution funnel 18, the inner wall at the right side of the distribution funnel 18 is provided with a distribution component 903, the distribution component 903 can be connected with the cloth baffle plate 19 at the right wall of the distribution funnel 18 in a sliding manner in a left-right reciprocating manner to enable the material in the distribution funnel 18 to fall uniformly, so that the distribution function is realized, the outer end at the left side of the stirring cavity 70 is provided with a left support plate 73, a discharging shaft 34 is rotatably connected onto the left support plate 73, a discharging component 904 is arranged on the discharging shaft 34, and the discharging component 904 comprises a discharging gear 33 arranged on the discharging shaft 34 and a discharging rack 14 which is slidably connected with the, the rotation through blowing gear 33 drives blowing rack 14 and removes about, realizes the blowing function of material in the stirring chamber 70, be equipped with on the blowing axle 34 and be located the one-way bearing 905 of blowing gear 33 front side, the selection of rotation direction can be realized to one-way bearing 905.
Beneficially, a driving wheel 24 is arranged on the motor shaft 26, a driven shaft 20 is rotatably connected to the T-shaped sliding block 21, a driven wheel 22 is arranged on the driven shaft 20, a belt 23 is connected between the driving wheel 24 and the driven wheel 22, a main bevel gear 53 is arranged at the lower end of the driven shaft 20, a material distribution area 15 is arranged on the inner wall of the rear side of the working cavity 12, and the material in the material distribution hopper 18 falls onto the material distribution area 15 to complete material distribution.
According to an embodiment, the traverse assembly 901 is described in detail below, the traverse assembly 901 further includes a disc shaft 52 rotatably connected to the right support plate 38, the disc shaft 52 is provided with a secondary bevel gear 54 engaged with the primary bevel gear 53, the primary bevel gear 53 rotates to provide power for the traverse assembly 901, the disc shaft 52 is provided with a disc 51, the disc 51 is provided with a protruding point 50, the disc shaft 52 is provided with a sector gear 35 located in front of the disc 51, the right support plate 38 is rotatably connected with a disc shaft 56 located below the disc shaft 52, the disc shaft 56 is provided with a grooved disc 49 capable of abutting against the sector gear 35 and a primary pulley 46 located in front of the grooved disc 49, the grooved disc 49 is provided with six sliding push grooves 48 slidably connected with the protruding point 50 and distributed in an annular array, when the protruding point 50 is slidably connected with the sliding push grooves 48, the fluted disc 49 rotates sixty degrees, the fluted disc shaft 56 is provided with a traverse gear 55 positioned at the rear side of the right support plate 38, the inner wall at the rear side of the working cavity 12 is provided with a traverse rack 13 engaged and connected with the traverse gear 55, and the rotation of the traverse gear 55 drives the right support plate 38 to move left and right.
According to an embodiment, the cloth component 903 is described in detail below, the cloth component 903 further includes an epicyclic shaft 58 rotatably connected to the right support plate 38 and located behind the fluted disc shaft 56, a secondary pulley 44 is disposed at a front end of the epicyclic shaft 58, a discharge belt 45 is connected between the secondary pulley 44 and the primary pulley 46, and the diameter of the primary pulley 46 is six times that of the secondary pulley 44, so that when the primary pulley 46 rotates sixty degrees, the secondary pulley 44 rotates one circle, and the epicyclic rod 42 rotates one circle, the epicyclic shaft 58 is disposed with an epicyclic rod 42, the epicyclic rod 42 is disposed with a sliding protrusion 41, the right support plate 38 is rotatably connected with an articulated rod shaft 57 located above the epicyclic shaft 58, the articulated rod shaft 57 is disposed with an articulated rod 40, the articulated rod 40 is disposed with a sliding groove 74 slidably connected with the sliding protrusion 41, the articulated rod 40 is articulated with a connecting rod 43, the connecting rod 43 is articulated with the material distribution baffle 19, the turnover rod 42 rotates for a circle, and the material distribution baffle 19 is driven to move rightwards and reset through the sliding salient point 41, the articulated rod 40 and the connecting rod 43 in sequence, so that a material distribution process is realized.
In the following, the emptying assembly 904 is described in detail according to an embodiment, the emptying assembly 904 further comprises a swinging shaft 60 rotatably connected with the right support plate 38, the swing shaft 60 is provided with a swing rod 39 which can be abutted against the salient point 50, the right support plate 38 is provided with a fixed block 36, a return spring 37 is connected between the fixed block 36 and the swinging rod 39, a swinging gear 61 positioned at the rear end of the right support plate 38 is arranged on the swinging shaft 60, a reversing shaft 59 is rotatably connected on the right support plate 38, a reversing gear 62 meshed with the swinging gear 61 is arranged on the reversing shaft 59, a belt pulley 75 positioned at the rear side of the reversing gear 62 is arranged on the reversing shaft 59, a discharging belt 32 is connected between the belt pulley 75 and the one-way bearing 905, the lower end of the emptying rack 14 is provided with a suspension bracket 16, and the suspension bracket 16 and the left end face of the distribution funnel 18 are connected with a spring 17.
According to the embodiment, the following detailed description is given to the one-way bearing 905, the one-way bearing 905 further comprises a bearing box 65 rotatably connected with the discharging shaft 34, a rotating cavity 66 is arranged in the bearing box 65, a bearing wheel 63 fixedly connected with the discharging shaft 34 is arranged in the rotating cavity 66, six selecting teeth 68 distributed in an annular array are arranged on the bearing wheel 63, a bearing spring 69 is connected between the selecting teeth 68 and the bearing wheel 63, a bearing block 64 capable of abutting against the selecting teeth 68 is arranged on the bearing wheel 63, six thrust teeth 67 distributed in an annular array and abutting against the selecting teeth 68 are arranged on the inner wall of the rotating cavity 66, the selecting teeth 68 abut against the bearing block 64, the selecting teeth 68 abut against the thrust teeth 67, and the thrust teeth are in different motion states.
The following will explain in detail the use steps of a quartz stone plate material distribution device in the present disclosure with reference to fig. 1 to 8:
initial state: the oscillating rod 39 is in a horizontal state, the distributing baffle 19 extends into the distributing hopper 18 to ensure that the upper part and the lower part in the distributing hopper 18 are not communicated, the discharging rack 14 is hermetically connected with the through hole 72 to ensure that the stirring cavity 70 is not communicated with the outside, and the T-shaped sliding block 21 is positioned at the rightmost end.
When materials are proportionally placed into the stirring cavity 70, the motor 25 is started to rotate the motor shaft 26, the motor shaft 26 sequentially passes through the rotating rod 29 and the left-right symmetrical stirring rod 30 to drive the left-right symmetrical stirring blades 31 to stir the mixed materials in the stirring cavity 70, so as to realize the stirring function, at the moment, the hinge rod shaft 57, the belt 23 and the driven wheel 22 drive the driven shaft 20 to rotate, the rotation of the driven shaft 20 sequentially passes through the main bevel gear 53, the auxiliary bevel gear 54, the disc shaft 52 and the disc 51 to drive the salient point 50 to rotate clockwise, the salient point 50 is abutted against the swinging rod 39, the swinging rod 39 swings, the reset spring 37 accumulates elastic potential energy in the process, and sequentially passes through the swinging shaft 60, the swinging gear 61 and the reversing gear 62 to drive the belt pulley 75 to rotate clockwise, and further sequentially passes through the discharging belt 32, the material distribution component 903 and, the clockwise rotation of the discharging gear 33 drives the discharging rack 14 to move leftwards, the material in the stirring cavity 70 falls into the material distributing hopper 18 and is blocked by the material distributing baffle 19 to prevent falling, in the process, the spring 17 accumulates elastic potential energy, when the salient point 50 is not abutted to the swinging rod 39, the return spring 37 releases the elastic potential energy to drive the swinging rod 39 to restore to the horizontal state, meanwhile, the spring 17 releases the elastic potential energy to drive the discharging rack 14 to reset through the suspension bracket 16, when the salient point 50 is in sliding connection with the sliding push groove 48, the salient point 50 drives the groove disc 49 to rotate sixty degrees anticlockwise through the sliding push groove 48, the rotation of the groove disc 49 drives the traverse gear 55 to rotate anticlockwise through the groove disc shaft 56, and drives the right support plate 38, the stirring container 28 and the material distributing hopper 18 to move leftwards due to the meshing relationship of the traverse gear 55 and the traverse rack 13, in the process, the groove disc 49 sequentially passes through the groove disc shaft, The main belt wheel 46 and the emptying belt 45 drive the auxiliary belt wheel 44 to rotate anticlockwise for a circle, meanwhile, the auxiliary belt wheel 44 sequentially passes through the revolving shaft 58, the revolving rod 42, the sliding salient points 41, the sliding groove 74, the hinge rod 40 and the connecting rod 43 to drive the material distribution baffle plate 19 to move rightwards, materials stored in the material distribution hopper 18 uniformly fall on the material distribution area 15 to complete material distribution work, and along with the rotation of the auxiliary belt wheel 44, at the moment, the auxiliary belt wheel 44 sequentially passes through the revolving shaft 58, the revolving rod 42, the sliding salient points 41, the sliding groove 74, the hinge rod 40 and the connecting rod 43 to drive the material distribution baffle plate 19 to move leftwards, so that the next. After the whole material distribution process is finished, the motor 25 is rotated reversely until the device returns to the initial state, and the motor 25 is turned off.
The invention has the beneficial effects that: the invention adopts the one-way bearing, ensures that partial components do not move when the device is in the initial state, adopts the grooved pulley to ensure that the material distribution process is carried out step by step, adopts the material distribution hopper to ensure that the material has a storage space during each material discharge, ensures the material distribution work, and improves the conditions that the material directly falls from the container, has no intermediate medium, can have uneven material distribution and needs secondary treatment when most of the prior quartz stone plate material distributor distributes materials, thus not only the product quality can not be ensured, but also the current situations of large amount of manpower and material resources can be wasted.
In the above manner, a person skilled in the art can make various changes depending on the operation mode within the scope of the present invention.