CN114011701B - Sand and soil separating equipment for hydraulic engineering capital construction manufacturing - Google Patents

Abstract

The invention relates to sand and soil separation equipment, in particular to sand and soil separation equipment for hydraulic engineering capital construction. The invention provides sand and soil separating equipment for hydraulic engineering infrastructure manufacturing, which can automatically screen impurities, automatically collect the impurities and relieve the dropping rate of sand and soil. Sand and soil separation equipment for hydraulic engineering capital construction manufacture includes: the middle part of the upper side of the working box is provided with a funnel; the collecting frame is arranged at the lower part of the working box; the upper part of the working box is provided with a blocking mechanism; the first screening mechanism is arranged on the upper portion of the working box. According to the invention, the sand is screened through the first filter screen, so that impurities are left on the first filter screen, the sand can fall into the working box through the first filter screen, and the effect of collecting the impurities by the movable plate is realized.

Description

Sand and soil separating equipment for hydraulic engineering capital construction manufacturing

Technical Field

The invention relates to sand and soil separation equipment, in particular to sand and soil separation equipment for hydraulic engineering capital construction.

Background

There is a different proportion of sand in the soil in the south, and in some situations, a smaller amount of sand is required, for example, when treating harmful algae in rivers and Hu Bo, a smaller amount of sand is required, and a large amount of harmful algae exists in the south water area, for example: blue algae, diatom, dinoflagellate and the like, the algae have very strong reproductive capacity, excessively consume oxygen in water and destroy ecological environment in water, and researches show that soil can treat harmful algae, but the soil needs to be controlled in sand content, and in view of the fact that the sand content in the soil in the south is not small, the cost of transporting the soil from the north is very high, and meanwhile, the algae are unfavorable for the use of hydraulic engineering construction, so that construction equipment is easy to collapse.

The traditional sand and soil separation treatment mode is to wash and separate by using a water washing mode, so that the waste of water resources is caused, a large amount of dust pollutants are generated, the separation is not thorough enough, the finally separated impurities cannot be put into use, the work task of workers is increased, and the workers are required to collect the impurities.

Therefore, we design a kind of sand and soil separating equipment for hydraulic engineering construction which can automatically screen the impurity, automatically collect the impurity and relieve the dropping rate of sand and soil.

Disclosure of Invention

In order to overcome the defects that the traditional sand and soil separating equipment cannot automatically screen impurities, automatically collect the impurities and relieve the sand and soil dropping rate, the invention provides the sand and soil separating equipment for hydraulic engineering infrastructure manufacturing, which can automatically screen the impurities, automatically collect the impurities and relieve the sand and soil dropping rate.

The invention is realized in such a way that a sand and soil separating device for hydraulic engineering infrastructure manufacturing comprises:

the middle part of the upper side of the working box is provided with a funnel;

the collecting frame is arranged at the lower part of the working box;

the upper part of the working box is provided with a blocking mechanism;

the first screening mechanism is arranged on the upper portion of the working box.

Optionally, the plugging mechanism comprises:

the first electric push rod is arranged at the upper part of the working box;

the movable rod is arranged on two sides of the upper part of the working box in a sliding manner and is connected with the first electric push rod telescopic rod;

the material blocking plate is connected between the two movable rods;

the first pressure sensor is arranged on the blanking plate;

and the middle part of the collecting frame is provided with a second pressure sensor.

Optionally, the first screening mechanism comprises:

the upper part of the working box is provided with a movable plate in a sliding manner;

the movable plate is provided with a first filter screen;

the upper part of the working box is provided with a first travel switch which is matched with the second electric push rod telescopic rod;

the second electric push rod is arranged on the working box, and the second electric push rod telescopic rod is connected with the movable plate.

As a preferred embodiment of the present invention, the second screening means includes:

the working box is provided with a third electric push rod, and the telescopic rod of the third electric push rod is connected with the movable plate;

the second travel switch is arranged on the working box and is matched with the third electric push rod telescopic rod;

the movable plate is provided with a second filter screen.

As a preferred technical solution of the present invention, the discharging mechanism includes:

the driving motor is arranged at the upper part of the working box;

a reel is arranged on the output shaft of the driving motor;

the upper part of the working box is provided with a discharge plate in a sliding manner;

the first pull rope is connected between the discharging plate and the reel, and is connected with the working box in a sliding manner;

springs are connected between the working box and the discharging plate, and the number of the springs is six.

As a preferred technical solution of the present invention, the toggle mechanism includes:

the lower part of the funnel is provided with a movable ring;

the movable blocks are arranged on two sides of the movable plate and are connected with the working box in a sliding manner;

the second stay cords are connected between the movable ring and the movable block, and the number of the second stay cords is two.

As a preferred embodiment of the present invention, the buffer mechanism includes:

the servo motor is arranged on the working box;

the output shaft of the servo motor is connected with a rotating shaft which is rotationally connected with the working box;

the material blocking component is arranged on the rotating shaft.

As a preferable technical scheme of the invention, a control box is arranged at the lower part of the working box, a switching power supply, a control module and a power module are arranged in the control box, the switching power supply supplies power for sand and soil separating equipment for hydraulic engineering construction and manufacturing, the output end of the switching power supply is electrically connected with the power module, the power module is connected with a main power switch through a circuit, and the control module is electrically connected with the power module; the control module is connected with a DS1302 clock circuit and a 24C02 circuit; the first pressure sensor, the second pressure sensor, the first travel switch and the second travel switch are all electrically connected with the control module, the first electric push rod, the second electric push rod and the third electric push rod are all connected with the control module through the relay control module, the driving motor is connected with the control module through the direct current motor positive and negative rotation module, and the servo motor is connected with the control module through the servo motor driving module.

The invention provides sand and soil separation equipment for hydraulic engineering infrastructure construction. The beneficial effects are as follows:

1. according to the invention, the sand is screened through the first filter screen, so that impurities are left on the first filter screen, the sand can fall into the working box through the first filter screen, and the effect of collecting the impurities by the movable plate is realized;

2. according to the invention, the first pull rope drives the discharge plate to move upwards, the spring is compressed, so that the discharge plate opens the outlet of the working box, and impurities on the first filter screen flow down to the movable plate through the outlet of the working box, thereby realizing the effect of impurity flow down;

3. according to the invention, fine impurities are screened through the second filter screen, so that the fine impurities are left on the second filter screen, sand falls into the working box through the second filter screen, and the sand falls onto the collecting frame through the working box flow, so that the effect of screening the fine impurities by the second filter screen is realized;

4. according to the invention, after sand falls into contact with the material blocking component through the working box, the material blocking component buffers the sand, so that the sand is prevented from flowing out of the collecting frame due to too fast flow speed, and the effect of buffering the sand by the material blocking component is realized.

Drawings

Fig. 1 is a schematic perspective view of a first embodiment of the present invention.

Fig. 2 is a schematic perspective view of a second embodiment of the present invention.

Fig. 3 is a schematic perspective view of a first plugging mechanism according to the present invention.

Fig. 4 is a schematic perspective view of a second plugging mechanism according to the present invention.

Fig. 5 is a schematic perspective view of a third plugging mechanism according to the present invention.

Fig. 6 is a schematic perspective view of a first screening mechanism according to the present invention.

Fig. 7 is a schematic perspective view of a second screening mechanism according to the present invention.

Fig. 8 is a schematic perspective view of a third first screening mechanism according to the present invention.

Fig. 9 is a schematic perspective view of a first screening mechanism according to the present invention.

Fig. 10 is a schematic perspective view of a second screening mechanism according to the present invention.

Fig. 11 is a schematic perspective view of a first discharging mechanism according to the present invention.

Fig. 12 is a schematic perspective view of a second discharging mechanism according to the present invention.

Fig. 13 is a schematic perspective view of a toggle mechanism according to the present invention.

Fig. 14 is a schematic perspective view of a first buffer mechanism according to the present invention.

Fig. 15 is a schematic perspective view of a second cushioning mechanism according to the present invention.

Fig. 16 is a circuit block diagram of the present invention.

Fig. 17 is a schematic circuit diagram of the present invention.

Reference numerals illustrate: 1_working box, 2_hopper, 3_collecting frame, 4_control box, 5_blanking mechanism, 51_first electric push rod, 52_movable rod, 53_blanking plate, 54_first pressure sensor, 55_second pressure sensor, 6_first screening mechanism, 61_movable plate, 62_first filter screen, 63_first travel switch, 64_second electric push rod, 7_second screening mechanism, 71_third electric push rod, 72_second travel switch, 73_second filter screen, 8_discharging mechanism, 81_driving motor, 82_reel, 83_first pull rope, 84_discharging plate, 85_spring, 9_toggle mechanism, 91_movable ring, 92_second pull rope, 93_movable block, 10_buffer mechanism, 101_blocking part, 102_servo motor, 103_rotating shaft.

Detailed Description

The present invention will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present invention more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

Referring to fig. 1 to 17, the present invention provides a technical solution: the utility model provides a hydraulic engineering capital construction is sand and soil splitter for manufacturing, is equipped with funnel 2 including work box 1, funnel 2, collection frame 3, putty mechanism 5 and first screening mechanism 6 in the middle part of work box 1 upside, and work box 1 rear side lower part is equipped with collects frame 3, and work box 1 upper portion is equipped with putty mechanism 5, and work box 1 upper portion is equipped with first screening mechanism 6.

The material blocking mechanism 5 comprises a first electric push rod 51, a movable rod 52, a material blocking plate 53, a first pressure sensor 54 and a second pressure sensor 55, wherein the first electric push rod 51 is arranged on the left side of the upper portion of the working box 1, the movable rod 52 is arranged on the front side and the rear side of the upper portion of the working box 1 in a sliding mode, the movable rod 52 is connected with a telescopic rod of the first electric push rod 51, the material blocking plate 53 is connected between the two movable rods 52, the first pressure sensor 54 is arranged on the material blocking plate 53, and the second pressure sensor 55 is arranged in the middle of the collecting frame 3.

The first screening mechanism 6 comprises a movable plate 61, a first filter screen 62, a first travel switch 63 and a second electric push rod 64, wherein the movable plate 61 is arranged on the upper portion of the working box 1 in a sliding mode, the first filter screen 62 is arranged on the movable plate 61, the first travel switch 63 is arranged on the left side of the upper portion of the working box 1, the first travel switch 63 is matched with a telescopic rod of the second electric push rod 64, the second electric push rod 64 is arranged on the left side of the rear portion of the working box 1, and the telescopic rod of the second electric push rod 64 is connected with the movable plate 61.

The second screening mechanism 7 comprises a third electric push rod 71, a second travel switch 72 and a second filter screen 73, wherein the third electric push rod 71 is installed on the left side of the rear portion of the working box 1, a telescopic rod of the third electric push rod 71 is connected with the movable plate 61, the third electric push rod 71 is located below the second electric push rod 64, the second travel switch 72 is arranged on the left side of the rear portion of the working box 1, the second travel switch 72 is matched with the telescopic rod of the third electric push rod 71, the second filter screen 73 is arranged on the movable plate 61, and the second filter screen 73 is located below the first filter screen 62.

Still including discharge mechanism 8, discharge mechanism 8 is including driving motor 81, reel 82, first stay 83, flitch 84 and spring 85, and driving motor 81 is installed on the right side of work box 1 upper portion, is equipped with reel 82 on the 81 output shaft of driving motor, and work box 1 front side upper portion slidingtype is equipped with flitch 84, is connected with first stay 83 between flitch 84 and the reel 82, and first stay 83 is connected with work box 1 slidingtype, is connected with spring 85 between work box 1 and the flitch 84, and spring 85 quantity is six.

Still including toggle mechanism 9, toggle mechanism 9 is equipped with the expansion loop 91 including expansion loop 91, second stay 92 and movable block 93, funnel 2 lower part, and both sides all are equipped with movable block 93 around the fly leaf 61, and movable block 93 is connected with work box 1 slidingtype, is connected with second stay 92 between expansion loop 91 and the movable block 93, and second stay 92 quantity is two.

The buffer mechanism 10 comprises a material blocking part 101, a servo motor 102 and a rotating shaft 103, wherein the servo motor 102 is arranged on the right part of the rear side of the working box 1, the rotating shaft 103 is connected to an output shaft of the servo motor 102, the rotating shaft 103 is rotatably connected with the working box 1, and the material blocking part 101 is arranged on the rotating shaft 103.

The control box 4 is arranged at the lower part of the rear side of the working box 1, a switching power supply, a control module and a power module are arranged in the control box 4, the switching power supply supplies power for sand and soil separating equipment for hydraulic engineering construction and manufacturing, the output end of the switching power supply is electrically connected with the power module, the power module is connected with a main power switch through a circuit, and the control module is electrically connected with the power module; the control module is connected with a DS1302 clock circuit and a 24C02 circuit; the first pressure sensor 54, the second pressure sensor 55, the first travel switch 63 and the second travel switch 72 are all electrically connected with a control module, the first electric push rod 51, the second electric push rod 64 and the third electric push rod 71 are all connected with the control module through a relay control module, the driving motor 81 is connected with the control module through a direct current motor forward/reverse rotation module, and the servo motor 102 is connected with the control module through a servo motor driving module.

The working principle of the invention is that when people want to separate sand, the sand separating device for hydraulic engineering infrastructure manufacturing can be used, firstly, a user presses a power supply main switch to electrify the device, then the user pours the sand into a hopper 2, a material blocking mechanism 5 stops the sand so that the sand cannot fall, when the weight of the sand reaches a preset value of the material blocking mechanism 5, the control module controls the material blocking mechanism 5 to move rightwards for one second, after one second, the control module controls the material blocking mechanism 5 to be static, meanwhile, the control module controls the first screening mechanism 6 to operate, the sand falls on the first screening mechanism 6 through the hopper 2, the first screening mechanism 6 is used for collecting impurities, after ten minutes, the control module controls the first screening mechanism 6 to stop operating, the sand falls into a working box 1 through the first screening mechanism 6, the sand is influenced by the self angle of the working box 1, the sand falls into a collection frame 3 through the working box 1, when the weight of the sand is preset value of the material blocking mechanism 5 is set for one second, and then the control module controls the hopper 5 to stop the power supply main switch to stop when the sand falls into the collection frame 3, and the power supply main switch is controlled to stop the power supply mechanism 5 for one second.

After the user pours sand into funnel 2, the sand drops on the putty plate 53 through funnel 2, the putty plate 53 blocks sand, make sand unable to drop, when the weight of sand reaches the preset value of first pressure sensor 54, make the control module control first electric putter 51 telescopic link shorten one second to the right, first electric putter 51 telescopic link drives movable rod 52 to move to the right, movable rod 52 drives putty plate 53 to move to the right, putty plate 53 drives first pressure sensor 54 to move to the right, thereby after the putty plate 53 moves to the right and breaks away from funnel 2, thereby open funnel 2 passageway, sand falls in work box 1 through funnel 2 passageway, after one second, control module control first electric putter 51 telescopic link is static, sand flows in collection frame 3 through work box 1, when the weight of sand reaches the preset value of second pressure sensor 55, make the control module control first electric putter 51 telescopic link extend one second to the left, first electric putter 51 telescopic link drives movable rod 52, material plate 53 and first pressure sensor 54 move to the right, make sand flow into funnel 2 through the left, thereby the putty plate 53 can't flow into work box 1 through funnel 2.

When the weight of the sand reaches the preset value of the first pressure sensor 54, the control module controls the second electric push rod 64 to work, the second electric push rod 64 stretches the telescopic rod leftwards for one second, the second electric push rod 64 stretches the movable plate 61 leftwards, the movable plate 61 drives the first filter screen 62 to move leftwards, after one second, the control module controls the second electric push rod 64 to stretch the telescopic rod rightwards for one second, the second electric push rod 64 stretches the movable plate 61 and the first filter screen 62 to move rightwards, the first filter screen 62 forms shaking force, the sand falls on the first filter screen 62 through the funnel 2, the first filter screen 62 screens the sand, impurities are left on the first filter screen 62, the sand falls in the working box 1 through the first filter screen 62 and are influenced by the angle of the first filter screen 62, the impurities fall in the movable plate 61 through the first filter screen 62, the movable plate 61 collects the impurities, after ten minutes, the control module controls the second electric push rod 64 to stretch rightwards for two seconds, the second electric push rod 64 is driven by the control module to stretch the second electric push rod 64 to stretch rightwards, the second electric push rod 64 is driven by the first filter screen 62 to stop moving rightwards, and the first filter screen 64 is contacted with the second electric push rod 64 to stop moving rightwards, and the first filter screen 64 stops moving rightwards.

When the weight of the sand reaches the preset value of the first pressure sensor 54, the control module controls the third electric push rod 71 to work, the telescopic rod of the third electric push rod 71 stretches leftwards for one second, the telescopic rod of the third electric push rod 71 drives the movable plate 61 to move leftwards, the movable plate 61 drives the second filter screen 73 to move leftwards, after one second, the control module controls the telescopic rod of the third electric push rod 71 to shorten rightwards for one second, the telescopic rod of the third electric push rod 71 drives the movable plate 61 and the second filter screen 73 to move rightwards, the second filter screen 73 forms a shaking force, the sand falls on the second filter screen 73 through the first filter screen 62, and because fine impurities exist in the sand, the second filter screen 73 screens the fine impurities, the fine impurities remain on the second filter screen 73, the sand falls on the working box 1 through the second filter screen 73, the sand falls on the collecting frame 3 again through the working box 1, after ten minutes, the control module controls the telescopic rod of the third electric push rod 71 to shorten rightwards, the second electric push rod 71 moves rightwards, the third electric push rod 71 and the second electric push rod 71 stops moving rightwards, and the second electric push rod is stopped to move rightwards, and the second push rod is stopped.

When the telescopic rod of the second electric push rod 64 is shortened to the right and is in contact with the first travel switch 63, the control module controls the driving motor 81 to work for five seconds, the output shaft of the driving motor 81 drives the reel 82 to rotate, the reel 82 pulls the first pull rope 83, the first pull rope 83 drives the discharging plate 84 to move upwards, the spring 85 is compressed, the discharging plate 84 opens the outlet of the working box 1, impurities on the first filter screen 62 flow onto the movable plate 61 through the outlet of the working box 1, after five seconds, the control module controls the driving motor 81 to be static, when the weight of sand reaches the preset value of the second pressure sensor 55, the control module controls the driving motor 81 to reversely rotate for five seconds, the output shaft of the driving motor 81 drives the reel 82 to reversely rotate, the reel 82 releases the first pull rope 83, the spring 85 is reset, the discharging plate 84 is driven to move downwards, the discharging plate 84 pulls the first pull rope 83, and the outlet of the working box 1 is closed by the discharging plate 84.

After the user pours sand into the funnel 2, there is some sand left in the funnel 2, when the fly leaf 61 moves left, the fly leaf 61 drives the movable block 93 to move left, the movable block 93 pulls the second stay 92, the second stay 92 drives the movable ring 91 to move left, when the fly leaf 61 moves right, the fly leaf 61 drives the movable block 93 to move right, the movable block 93 pulls the second stay 92, the second stay 92 drives the movable ring 91 to move right, slight left-right movement through the movable ring 91, the movable ring 91 stirs the funnel 2, make sand continue to drop on the first filter screen 62 through the funnel 2.

When the telescopic rod of the third electric push rod 71 is shortened to the right and contacts with the second travel switch 72, the control module controls the output shaft of the servo motor 102 to rotate for one second, the output shaft of the servo motor 102 drives the rotating shaft 103 to rotate, the rotating shaft 103 drives the material blocking component 101 to rotate, after one second, the control module controls the output shaft of the servo motor 102 to be static, sand falls into contact with the material blocking component 101 through the working box 1, the material blocking component 101 buffers sand and prevents the sand from flowing out of the collecting frame 3 due to too fast flow speed, when the weight of the sand reaches a preset value of the second pressure sensor 55, the control module controls the output shaft of the servo motor 102 to reversely rotate for one second, the output shaft of the servo motor 102 drives the rotating shaft 103 and the material blocking component 101 to reversely rotate, and after one second, the control module controls the output shaft of the servo motor 102 to be static.

The foregoing is merely illustrative of the present invention, and the present invention is not limited thereto, and any person skilled in the art will readily recognize that variations or substitutions are within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (6)

1. Sand and soil separating equipment for hydraulic engineering capital construction manufacture, characterized by comprising:

the middle part of the upper side of the working box (1) is provided with a funnel (2);

the collecting frame (3) is arranged at the lower part of the working box (1);

the upper part of the working box (1) is provided with a blocking mechanism (5);

the first screening mechanism (6) is arranged at the upper part of the working box (1);

the blocking mechanism (5) comprises:

the first electric push rod (51) is arranged at the upper part of the working box (1);

the movable rod (52) is arranged on two sides of the upper part of the working box (1) in a sliding mode, the movable rod (52) is connected with the telescopic rod of the first electric push rod (51);

a material blocking plate (53), wherein the material blocking plate (53) is connected between the two movable rods (52);

the first pressure sensor (54) is arranged on the blanking plate (53);

the second pressure sensor (55) is arranged in the middle of the collecting frame (3), and the second pressure sensor (55) is arranged in the middle of the collecting frame;

the first screening means (6) comprises:

a movable plate (61), wherein the movable plate (61) is arranged on the upper part of the working box (1) in a sliding manner;

a first filter screen (62), wherein the movable plate (61) is provided with the first filter screen (62);

the first travel switch (63) is arranged at the upper part of the working box (1), and the first travel switch (63) is matched with a telescopic rod of the second electric push rod (64);

and the second electric push rod (64) is arranged on the working box (1), and the telescopic rod of the second electric push rod (64) is connected with the movable plate (61).

2. The sand and soil separating device for hydraulic engineering infrastructure manufacturing according to claim 1, further comprising a second screening mechanism (7), wherein the second screening mechanism (7) comprises:

the third electric push rod (71), install the third electric push rod (71) on the working box (1), the telescopic link of the third electric push rod (71) is connected with movable plate (61);

the second travel switch (72) is arranged on the working box (1), and the second travel switch (72) is matched with the telescopic rod of the third electric push rod (71);

the second filter screen (73), be equipped with second filter screen (73) on fly leaf (61).

3. The sand and soil separating device for hydraulic engineering capital construction according to claim 2, further comprising a discharging mechanism (8), wherein the discharging mechanism (8) comprises:

a driving motor (81), wherein the driving motor (81) is arranged at the upper part of the working box (1);

a reel (82), wherein the output shaft of the driving motor (81) is provided with the reel (82);

a discharging plate (84), wherein the discharging plate (84) is arranged at the upper part of the working box (1) in a sliding manner;

a first pull rope (83), wherein the first pull rope (83) is connected between the discharging plate (84) and the reel (82), and the first pull rope (83) is connected with the working box (1) in a sliding manner;

and springs (85) are connected between the working box (1) and the discharging plate (84), and the number of the springs (85) is six.

4. A sand and soil separating device for hydraulic engineering construction according to claim 3, further comprising a toggle mechanism (9), wherein the toggle mechanism (9) comprises:

a movable ring (91), wherein the lower part of the funnel (2) is provided with the movable ring (91);

the movable blocks (93) are arranged on two sides of the movable plate (61), and the movable blocks (93) are connected with the working box (1) in a sliding mode;

and second pull ropes (92), wherein two second pull ropes (92) are connected between the movable ring (91) and the movable block (93).

5. The sand and soil separating apparatus for hydraulic engineering construction and manufacturing as claimed in claim 4, further comprising a buffer mechanism (10), wherein the buffer mechanism (10) comprises:

a servo motor (102), wherein the servo motor (102) is arranged on the working box (1);

the rotating shaft (103) is connected with the output shaft of the servo motor (102), and the rotating shaft (103) is rotationally connected with the working box (1);

the material blocking component (101) is arranged on the rotating shaft (103).

6. The sand and soil separating device for hydraulic engineering infrastructure manufacturing according to claim 5, further comprising a control box (4), wherein the control box (4) is arranged at the lower part of the working box (1), a switching power supply, a control module and a power module are arranged in the control box (4), the switching power supply supplies power for the sand and soil separating device for hydraulic engineering infrastructure manufacturing, the output end of the switching power supply is electrically connected with the power module, the power module is connected with a main power switch through a circuit, and the control module is electrically connected with the power module; the control module is connected with a DS1302 clock circuit and a 24C02 circuit; the first pressure sensor (54), the second pressure sensor (55), the first travel switch (63) and the second travel switch (72) are all electrically connected with the control module, the first electric push rod (51), the second electric push rod (64) and the third electric push rod (71) are all connected with the control module through the relay control module, the driving motor (81) is connected with the control module through the direct current motor forward and reverse rotation module, and the servo motor (102) is connected with the control module through the servo motor driving module.

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