CN115229987A - Concrete batching ratio real-time adjustment supervisory systems - Google Patents

Abstract

The invention relates to the technical field of batching proportioning devices, in particular to a concrete batching proportioning real-time adjusting and monitoring system, which comprises a bottom plate, a weigher, a weighing hopper and a lifting assembly, wherein the lifting assembly comprises two supports, a driving part, a cross rod, two lifting plates and two first racks; when need not weigh the batching, shift up through drive division drive horizontal pole, the horizontal pole drives two boards of lifting and shifts up, the board of lifting promotes the support and shifts up after contacting with the support, thereby make weighing to fight and move up and keep away from the weighing machine, no longer the weighing machine exerts pressure, when needs weigh again, control drive division drive board of lifting moves down and no longer to the support application of force, the fill of weighing then can move down to the weighing machine under the action of gravity this moment, can realize when not needing the batching, make weighing to fight and keep away from the weighing machine, avoid weighing to fight and cause the weighing machine to damage for a long time pressing on the weighing machine.

Description

Concrete batching ratio real-time adjustment supervisory systems

Technical Field

The invention relates to the technical field of batching proportioning devices, in particular to a concrete batching proportioning real-time adjusting and monitoring system.

Background

The concrete is prepared by mixing cement, sand, stone, water and other ingredients according to a certain proportion and stirring, and the ingredient proportion is controlled by the experience of workers when the concrete is prepared at present, so that the concrete is not accurate enough.

At present, the prior art discloses a concrete batching proportion real-time adjustment and supervision system which comprises a bottom plate, a weighing device and a weighing hopper, wherein the weighing device is fixed on the bottom plate, the weighing hopper is fixed on the weighing device, and the weighing hopper is weighed through the weighing device, so that the accuracy is higher.

However, by adopting the mode, the weighing hopper is pressed on the weighing device when the materials are proportioned or not proportioned, the weighing device is always in a load state, and the weighing device is easy to damage after long-time use.

Disclosure of Invention

The invention aims to provide a concrete batching proportion real-time adjusting and monitoring system which can enable a weighing hopper to be far away from a weighing device when batching is not needed, and avoid damage to the weighing device caused by long-time pressing of the weighing hopper on the weighing device.

In order to achieve the purpose, the invention provides a concrete batching proportion real-time adjusting and monitoring system which comprises a bottom plate, a weighing device, a weighing hopper and a lifting assembly, wherein the weighing device is fixedly connected with the bottom plate and positioned at the top of the bottom plate, the weighing hopper is positioned at the top of the weighing device, and the lifting assembly comprises two supports, a driving part, a cross rod, two lifting plates and two first racks;

the two support seats are respectively fixedly connected with the weighing hoppers and are positioned at two sides of the weighing hoppers; the driving part is arranged at the top of the bottom plate; the cross bar is arranged on the side edge of the driving part; the two lifting plates are respectively fixedly connected with the cross rod and are positioned on two sides of the cross rod; two first racks respectively with two lift board fixed connection, and respectively with two support sliding connection, and be located two respectively lift board top.

The lifting assembly further comprises two reinforcing parts, the two reinforcing parts are positioned on two sides of the weighing hopper, and each reinforcing part comprises a support, a threaded column and a supporting block; the bracket is fixedly connected with the bottom plate and is positioned at the top of the bottom plate; the threaded column is in threaded connection with the bracket and penetrates through the bracket; the supporting block is rotatably connected with the threaded column and is positioned at the top of the threaded column.

Wherein the reinforcing part further comprises a knob; the knob is fixedly connected with the threaded column and is positioned at the bottom of the threaded column.

The driving part comprises a guide rail, a sliding block and a screw rod; the guide rail is fixedly connected with the bottom plate and is positioned at the top of the bottom plate; the sliding block is connected with the guide rail in a sliding manner, is fixedly connected with the cross rod and is positioned on the side edge of the guide rail; the screw rod is rotationally connected with the guide rail, is in threaded connection with the sliding block and is positioned on the side edge of the guide rail.

The concrete batching proportion real-time adjusting and monitoring system further comprises a discharging assembly; the discharging component is arranged at the bottom of the discharging hopper.

The discharging assembly comprises a feeding channel, a feeding auger, a discharging pipe and a rotating part; the feeding channel is fixedly connected and communicated with the weighing hopper and is positioned at the bottom of the weighing hopper; the feeding auger is rotationally connected with the feeding channel and is positioned in the feeding channel; the discharge pipe is fixedly connected and communicated with the feeding auger and is positioned on one side of the feeding auger; the rotating part sets up pay-off auger side.

The rotating part comprises a mounting seat, a motor and a connecting shaft; the mounting seat is fixedly connected with the feeding channel and is positioned on the side edge of the feeding channel; the motor is fixedly connected with the mounting seat and is positioned on the side edge of the mounting seat; the connecting axle with motor output fixed connection, and with pay-off auger fixed connection, and be located the motor with between the pay-off auger.

According to the real-time adjusting and monitoring system for the proportioning of the concrete ingredients, when the concrete ingredients are proportioned, the concrete ingredients are firstly placed into the weighing hopper, the lifting plate is far away from the support, the weighing hopper is not stressed and is completely pressed on the weighing device, the weighing device is used for weighing the weight of the ingredients, a worker can monitor the weight of the ingredients in real time, and the ingredients can be added or reduced into the weighing hopper according to the required proportioning of the ingredients to be adjusted in real time; when the weighing machine needs to weigh again, the driving part is controlled to drive the lifting plate to move downwards without applying force to the support, and at the moment, the weighing hopper moves downwards to the weighing machine under the action of gravity; a slotted hole matched with the first rack is formed in the support, the first rack can provide a guiding effect for the support, and the weighing hopper is prevented from deviating in position; by the aid of the mode, the weighing hopper can be kept away from the weighing device when batching is not needed, and damage to the weighing device caused by long-time pressing of the weighing hopper on the weighing device is avoided.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below.

Fig. 1 is an overall configuration diagram of the first embodiment of the present invention.

Fig. 2 is a structural diagram of the first embodiment of the present invention from another angle as a whole.

Fig. 3 is an overall side sectional view of the first embodiment of the present invention.

Fig. 4 is an overall configuration diagram of the second embodiment of the present invention.

Figure 5 is an overall side sectional view of a second embodiment of the invention.

Fig. 6 is an overall configuration diagram of the third embodiment of the present invention.

Fig. 7 is another overall angle schematic diagram of the third embodiment of the present invention.

Fig. 8 is an overall front sectional view of the third embodiment of the present invention.

Fig. 9 is an overall side sectional view of a third embodiment of the invention.

101-bottom plate, 102-weigher, 103-weighing hopper, 104-lifting component, 105-support, 106-driving part, 107-cross bar, 108-lifting plate, 109-first rack, 110-reinforcing part, 111-support, 112-threaded column, 113-supporting block, 114-knob, 115-guide rail, 116-slider, 117-screw rod, 201-discharging component, 202-feeding channel, 203-feeding auger, 204-discharging pipe, 205-rotating part, 206-mounting seat, 207-motor, 208-connecting shaft, 301-dust-absorbing component, 302-dust-collecting channel, 303-negative pressure fan, 304-dust screen, 305-cleaning piece, 306-isolating piece, 307-rotating shaft, 308-first bevel gear, 309-gear, 310-rotating column, 311-cleaning brush, 312-third bevel gear, 313-baffle, 314-first connecting rod, 315-second rack, 316-folding door, 317-second connecting rod, 318-supporting seat, 319-gear.

Detailed Description

The first embodiment of the present application is:

referring to fig. 1-3, wherein fig. 1 is a schematic overall structure diagram of a first embodiment of the present invention, fig. 2 is a schematic overall structure diagram of another angle of the first embodiment of the present invention, fig. 3 is a side sectional view of the first embodiment of the present invention, the present invention provides a real-time adjustment and monitoring system for concrete batching ratio, which includes a bottom plate 101, a weighing machine 102, a weighing hopper 103 and a lifting assembly 104, wherein the lifting assembly 104 includes two supports 105, a driving portion 106, a cross bar 107, two lifting plates 108, two first racks 109 and two reinforcing portions 110; the reinforcing part 110 comprises a bracket 111, a threaded column 112, a supporting block 113 and a knob 114; the driving portion 106 includes a guide rail 115, a slider 116, and a lead screw 117.

For the present embodiment, the weighing device 102 is fixedly connected to the bottom plate 101, and is located at the top of the bottom plate 101, and the weighing hopper 103 is located at the top of the weighing device 102; the bottom plate 101 is used for supporting the weighing device 102, the weighing hopper 103 is used for storing concrete ingredients, and the weighing device 102 is used for weighing the ingredients in the weighing hopper 103.

The two support saddles 105 are respectively and fixedly connected with the weighing hopper 103 and are positioned at two sides of the weighing hopper 103; the driving part 106 is arranged on the top of the bottom plate 101; the cross bar 107 is arranged on the side of the driving part 106; the two lifting plates 108 are respectively fixedly connected with the cross rod 107 and are positioned on two sides of the cross rod 107; two first racks 109 respectively with two lift board 108 fixed connection, and respectively with two support 105 sliding connection, and be located two respectively lift board 108 top. When proportioning the concrete ingredients, firstly putting the concrete ingredients into the weighing hopper 103, then keeping the lifting plate 108 away from the support 105, completely pressing the weighing hopper 103 on the weighing device 102 without stress, weighing the weight of the ingredients by using the weighing device 102, and monitoring the weight of the ingredients by a worker in real time; when the ingredients are not required to be weighed, the driving part 106 drives the cross rod 107 to move upwards, the cross rod 107 drives the two lifting plates 108 to move upwards, the lifting plates 108 push the support 105 to move upwards after contacting with the support 105, so that the weighing bucket 103 moves upwards to be away from the weighing device 102, no pressure is applied to the weighing device 102, when weighing is required again, the driving part 106 is controlled to drive the lifting plates 108 to move downwards without applying force to the support 105, and at the moment, the weighing bucket 103 moves downwards to the weighing device 102 under the action of gravity; a slotted hole matched with the first rack 109 is formed in the support 105, and the first rack 109 can provide a guiding effect for the support 105, so that the position of the weighing hopper 103 is prevented from deviating; by the mode, when ingredients are not needed, the weighing hopper 103 is far away from the weighing device 102, and the weighing hopper 103 is prevented from being pressed on the weighing device 102 for a long time to cause damage to the weighing device 102.

Secondly, the two reinforcing parts 110 are positioned at two sides of the weighing hopper 103, and the bracket 111 is fixedly connected with the bottom plate 101 and positioned at the top of the bottom plate 101; the threaded column 112 is in threaded connection with the bracket 111 and penetrates through the bracket 111; the supporting block 113 is rotatably connected with the threaded column 112 and is located at the top of the threaded column 112. The support 111 is used for supporting the threaded column 112, the support block 113 is U-shaped and is adapted to the support base 105, when the weighing hopper 103 moves upwards, the threaded column 112 is rotated, the threaded column 112 drives the support block 113 to move upwards, so that the support block 113 is tightly abutted to the support base 105, and the support block 113 and the threaded column 112 can provide support for the support base 105, so that the weighing hopper 103 can be kept stable after moving upwards.

Meanwhile, the knob 114 is fixedly connected with the threaded column 112 and is located at the bottom of the threaded column 112. The knob 114 can be grasped by a user to facilitate rotation of the threaded post 112.

In addition, the guide rail 115 is fixedly connected with the bottom plate 101 and is positioned on the top of the bottom plate 101; the sliding block 116 is slidably connected with the guide rail 115, is fixedly connected with the cross bar 107 and is positioned on the side of the guide rail 115; the screw rod 117 is rotatably connected with the guide rail 115, is in threaded connection with the sliding block 116, and is positioned on the side of the guide rail 115. The screw rod 117 is rotated, so that the slide block 116 moves longitudinally along the guide rail 115, and the slide block 116 drives the cross rod 107 to move longitudinally, thereby controlling the two lifting plates 108 to move to drive the weighing hoppers 103 to move; the rotation driving method of the lead screw 117 is the prior art, and for example, the lead screw can be driven by a forward and reverse rotation motor, which is not limited herein.

According to the concrete batching proportion real-time adjusting and monitoring system, when the concrete batching is proportioned, the concrete batching is firstly placed into the weighing hopper 103, at the moment, the lifting plate 108 is far away from the support 105, the weighing hopper 103 is not stressed and is completely pressed on the weighing device 102, the weighing device 102 is utilized to weigh the weight of the batching, a worker can monitor the weight of the batching in real time, and the batching can be added or reduced into the weighing hopper 103 according to the required batching proportion to be adjusted in real time; when the weighing of the ingredients is not needed, the screw rod 117 is rotated forward, so that the sliding block 116 moves up longitudinally along the guide rail 115, the sliding block 116 drives the cross rod 107 to move up, the cross rod 107 drives the two lifting plates 108 to move up, the lifting plates 108 push the support 105 to move up after contacting with the support 105, so that the weighing hopper 103 moves up and is away from the weighing device 102, no pressure is applied to the weighing device 102, the support block 113 is U-shaped and is matched with the support 105, after the weighing hopper 103 moves up, the threaded column 112 is rotated, the threaded column 112 drives the support block 113 to move up, the support block 113 is tightly abutted against the support 105, the support block 113 and the threaded column 112 can provide support for the support 105, so that the weighing hopper 103 can be kept stable after moving up, when weighing needs to be performed again, the screw rod 117 is controlled to rotate reversely, the lifting plates 108 are driven to move down without applying force to the support 105, and at this time, the weighing hopper 103 moves down to the weighing device 102 under the action of gravity; by the mode, when ingredients are not needed, the weighing hopper 103 is far away from the weighing device 102, and the weighing hopper 103 is prevented from being pressed on the weighing device 102 for a long time to cause damage to the weighing device 102.

The second embodiment of the present application is:

on the basis of the first embodiment, please refer to fig. 4-5, wherein fig. 4 is a schematic overall structural diagram of the second embodiment of the present invention, fig. 5 is a side sectional view of the second embodiment of the present invention, the system for real-time adjusting and monitoring the mixture ratio of concrete provided by the present invention further includes a discharging assembly 201; the discharging assembly 201 comprises a feeding channel 202, a feeding auger 203, a discharging pipe 204 and a rotating part 205; the rotating portion 205 includes a mount 206, a motor 207, and a connecting shaft 208.

For the present embodiment, the discharging component 201 is disposed at the bottom of the discharging hopper. The discharging component 201 can facilitate discharging the ingredients in the weighing hopper 103.

The feeding channel 202 is fixedly connected and communicated with the weighing hopper 103 and is positioned at the bottom of the weighing hopper 103; the feeding auger 203 is rotationally connected with the feeding channel 202 and is positioned inside the feeding channel 202; the discharge pipe 204 is fixedly connected and communicated with the feeding auger 203 and is positioned on one side of the feeding auger 203; the rotating part 205 is arranged at the side edge of the feeding auger 203. Ingredients in the weighing hopper 103 fall into the feeding channel 202 under the action of gravity, the feeding auger 203 is driven to rotate by the rotating part 205, and the ingredients are conveyed to the discharging pipe 204 and discharged.

Secondly, the mounting seat 206 is fixedly connected with the feeding channel 202 and is located on the side of the feeding channel 202; the motor 207 is fixedly connected with the mounting seat 206 and is positioned on the side of the mounting seat 206; the connecting axle 208 with motor 207 output fixed connection, and with pay-off auger 203 fixed connection, and be located motor 207 with between the pay-off auger 203. The mounting seat 206 is used for supporting the motor 207, the motor 207 drives the connecting shaft 208 to rotate, and the connecting shaft 208 drives the feeding auger 203 to rotate, so that discharging is performed.

The real-time adjustment supervisory systems of concrete batching ratio of this embodiment, mount pad 206 is used for supporting motor 207, the batching in the weighing hopper 103 falls into under the action of gravity in the pay-off passageway 202, motor 207 drives connecting axle 208 is rotatory, connecting axle 208 drives pay-off auger 203 is rotatory, with the batching carry extremely discharging pipe 204 department discharges.

The third embodiment of the present application is:

referring to fig. 6 to 9 on the basis of the second embodiment, wherein fig. 6 is a schematic overall structure diagram of a third embodiment of the present invention, fig. 7 is a schematic overall structure diagram of the third embodiment of the present invention from another angle, fig. 8 is a front sectional view of the third embodiment of the present invention, fig. 9 is a side sectional view of the third embodiment of the present invention, and the real-time adjustment and supervision system for concrete batching ratio further includes a dust collection assembly 301; the dust collection assembly 301 comprises a dust collection channel 302, a negative pressure fan 303, a dust screen 304, a cleaning member 305 and two partitions 306; the cleaning piece 305 comprises a rotating shaft 307, two first bevel gears 308, a second bevel gear 309, a rotating column 310, a cleaning brush 311 and a third bevel gear 312; the spacer 306 includes a flap 313, a first link 314, a second rack 315, a folding door 316, a second link 317, a support base 318, and a gear 319.

For the present embodiment, the dust collecting channel 302 is fixedly connected with the weighing hopper 103 and is located at the side of the weighing hopper 103; the negative pressure fan 303 is fixedly connected with the dust collection channel 302 and is positioned inside the dust collection channel 302; the dust screen 304 is fixedly connected with the dust collecting channel 302 and is positioned inside the dust collecting channel 302; the cleaning pieces 305 are arranged on the side of the dust screen 304; the two spacers 306 are respectively disposed at the sides of the dust collecting channel 302. When ingredients are put into the weighing hopper 103, raised dust is generated, suction force can be generated by opening the negative pressure fan 303, dust is sucked into the dust collection channel 302, the dust is blocked by the dust screen 304 and falls to the bottom of the dust collection channel 302 to be collected, the cleaning piece 305 is used for cleaning the dust screen 304, and the isolating piece 306 can seal the dust collection channel 302 when not weighing, so that foreign matters are prevented from entering the dust collection channel 302.

Wherein, the rotating shaft 307 is rotatably connected with the dust collecting channel 302 and is positioned at one side of the dust collecting channel 302; the two first bevel gears 308 are respectively fixedly connected with the rotating shaft 307 and are positioned at two ends of the rotating shaft 307; the second bevel gear 309 is fixedly connected with the connecting shaft 208 and is meshed with the first bevel gear 308 close to the connecting shaft 208; the rotating column 310 is rotatably connected with the dust screen 304 and penetrates through the dust screen 304; the cleaning brush 311 is fixedly connected with the rotating column 310 and is positioned on the side edge of the rotating column 310; the third bevel gear 312 is fixedly connected to the rotary column 310 and is engaged with the first bevel gear 308 adjacent to the rotary column 310. When the motor 207 drives the connecting shaft 208 to rotate, the connecting shaft 208 drives the second bevel gear 309 to rotate, the second bevel gear 309 drives the first bevel gear 308 engaged with the second bevel gear 309 to rotate, the first bevel gear 308 drives the first bevel gear 308 at the other end to rotate through the rotating shaft 307, so that the third bevel gear 312 and the rotating column 310 are driven to rotate, and the rotating column 310 drives the cleaning brush 311 to rotate to prevent the dust screen 304 from being cleaned, so that the dust screen 304 is prevented from being blocked.

Secondly, the baffle 313 is connected with the dust collection channel 302 in a sliding way and is positioned at the side of the dust collection channel 302; the first connecting rod 314 is fixedly connected with the baffle 313 and is positioned at the side of the baffle 313; the second rack 315 is fixedly connected with the first link 314 and is located at the side of the first link 314; the folding door 316 is connected with the weighing hopper 103 and is positioned at one side of the weighing hopper 103; the second link 317 is fixedly connected to the second rack 315 and the folding door 316, and is located between the second rack 315 and the folding door 316; the supporting seat 318 is fixedly connected with the weighing hopper 103 and is positioned at the side edge of the weighing hopper 103; the gear 319 is rotatably connected with the supporting seat 318 and is engaged with the first rack 109 and the second rack 315 respectively. After the ingredients are weighed, the lifting plate 108 and the first rack 109 move upwards, the first rack 109 drives the gear 319 to rotate, the gear 319 drives the second rack 315 to move, so that the two second racks 315 are close to each other (a strip groove for the second rack 315 to pass through is arranged on the first rack 109), the second rack 315 drives the folding door 316 to move through the second connecting rod 317, so that the folding door 316 is stretched until the two folding doors 316 are in contact with each other, and meanwhile, the second rack 315 drives the baffle 313 to move when moving, so that the two baffles 313 are close to each other, and then the lifting plate 108 is in contact with the support 105 to drive the weighing hopper 103 to move upwards, the weighing hopper 103 is closed by the two folding doors 316, so that foreign matters are prevented from entering the weighing hopper 103 when not in use, and the dust collection channel 302 can be closed by the two baffles 313, so that the foreign matters are prevented from entering the dust collection channel 302; when the ingredients need to be weighed again, the lifting plate 108 and the first rack 109 move downwards to drive the two folding doors 316 to move away from each other and fold, so that the weighing hopper 103 is not closed any more, the ingredients can be added into the weighing hopper 103 for weighing, and meanwhile, the two baffles 313 also move away from each other to not close the dust collection channel 302 any more.

According to the concrete batching proportion real-time adjustment monitoring system of the embodiment, after batching and weighing are completed, the lifting plate 108 and the first rack 109 move upwards, the first rack 109 drives the gear 319 to rotate, the gear 319 drives the second rack 315 to move, so that the two second racks 315 approach to each other, the second rack 315 drives the folding door 316 to move through the second connecting rod 317, so that the folding door 316 is stretched until the two folding doors 316 contact with each other, and meanwhile, the second rack 315 drives the baffle 313 to move when moving, so that the two baffle 313 approach to each other, and then the lifting plate 108 can contact with the support 105 to drive the weighing hopper 103 to move upwards, so that the two folding doors 316 are used for sealing the weighing hopper 103, thereby preventing foreign matters from entering the weighing hopper 103 when not in use, and the two baffle 313 can be used for sealing the dust collection channel 302, thereby preventing foreign matters from entering the dust collection channel 302; when the ingredients need to be weighed again, the lifting plate 108 and the first rack 109 move downwards to drive the two folding doors 316 to move away from each other and fold, so that the weighing hoppers 103 are not closed any more, the ingredients can be added into the weighing hoppers 103 for weighing, and meanwhile, the two baffles 313 also move away from each other and do not close the dust collection channel 302 any more; when the ingredients in the weighing hopper 103 are discharged, the motor 207 drives the connecting shaft 208 to rotate, the connecting shaft 208 drives the second bevel gear 309 to rotate, the second bevel gear 309 drives the first bevel gear 308 engaged with the second bevel gear 309 to rotate, the first bevel gear 308 drives the first bevel gear 308 at the other end to rotate through the rotating shaft 307, so that the third bevel gear 312 and the rotating column 310 are driven to rotate, the rotating column 310 drives the cleaning brush 311 to rotate to avoid cleaning the dust screen 304, the dust screen 304 is prevented from being blocked, and the dust screen 304 is cleaned while discharging the ingredients.

While the above disclosure describes one or more preferred embodiments of the present invention, it is not intended to limit the scope of the claims to such embodiments, and one skilled in the art will understand that all or a portion of the processes performed in the above embodiments may be practiced without departing from the spirit and scope of the claims.

Claims (7)

1. A concrete batching proportion real-time adjustment and supervision system comprises a bottom plate, a weigher and a weighing hopper, wherein the weigher is fixedly connected with the bottom plate and is positioned at the top of the bottom plate, the weighing hopper is positioned at the top of the weigher,

the device also comprises a lifting assembly;

the lifting assembly comprises two supports, a driving part, a cross rod, two lifting plates and two first racks;

the two supports are respectively fixedly connected with the weighing hopper and are positioned on two sides of the weighing hopper; the driving part is arranged at the top of the bottom plate; the cross bar is arranged on the side edge of the driving part; the two lifting plates are respectively fixedly connected with the cross rod and are positioned on two sides of the cross rod; two first racks respectively with two lift board fixed connection, and respectively with two support sliding connection to be located two respectively lift the board top.

2. The concrete batching proportion real-time adjustment and supervision system according to claim 1,

the lifting assembly further comprises two reinforcing parts, the two reinforcing parts are located on two sides of the weighing hopper, and each reinforcing part comprises a support, a threaded column and a supporting block; the bracket is fixedly connected with the bottom plate and is positioned at the top of the bottom plate; the threaded column is in threaded connection with the bracket and penetrates through the bracket; the supporting block is rotatably connected with the threaded column and is positioned at the top of the threaded column.

3. The concrete batching proportion real-time adjustment and supervision system according to claim 2,

the reinforcing part also comprises a knob; the knob is fixedly connected with the threaded column and is positioned at the bottom of the threaded column.

4. The concrete batching proportion real-time adjustment and supervision system according to claim 3,

the driving part comprises a guide rail, a sliding block and a screw rod; the guide rail is fixedly connected with the bottom plate and is positioned at the top of the bottom plate; the sliding block is connected with the guide rail in a sliding manner, is fixedly connected with the cross rod and is positioned on the side edge of the guide rail; the screw rod is rotationally connected with the guide rail, is in threaded connection with the sliding block and is positioned on the side edge of the guide rail.

5. The concrete batching proportion real-time adjustment and supervision system according to claim 1,

the concrete batching proportion real-time adjusting and monitoring system also comprises a discharging component; the discharging component is arranged at the bottom of the discharging hopper.

6. The concrete batching proportion real-time adjustment and supervision system according to claim 5,

the discharging assembly comprises a feeding channel, a feeding auger, a discharging pipe and a rotating part; the feeding channel is fixedly connected and communicated with the weighing hopper and is positioned at the bottom of the weighing hopper; the feeding auger is rotationally connected with the feeding channel and is positioned in the feeding channel; the discharge pipe is fixedly connected and communicated with the feeding auger and is positioned on one side of the feeding auger; the rotating part sets up pay-off auger side.

7. The concrete batching proportion real-time adjustment and supervision system according to claim 6,

the rotating part comprises a mounting seat, a motor and a connecting shaft; the mounting seat is fixedly connected with the feeding channel and is positioned on the side edge of the feeding channel; the motor is fixedly connected with the mounting seat and is positioned on the side edge of the mounting seat; the connecting axle with motor output fixed connection, and with pay-off auger fixed connection, and be located the motor with between the pay-off auger.

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