CN210519498U - Concave plate gap automatic regulating system based on feeding amount and threshing and separating device - Google Patents

Abstract

The utility model discloses a concave clearance automatic regulating system and a threshing and separating device based on feeding amount, wherein the concave clearance automatic regulating system of the threshing and separating device based on feeding amount comprises a concave clearance regulating mechanism, an electric control system and a hydraulic system, the threshing and separating device comprises a threshing cylinder, a top cover and a concave, the threshing cylinder is positioned in a threshing chamber formed by the top cover and the concave, and the concave clearance regulating mechanism is used for regulating the concave clearance of the corn threshing and separating device; the hydraulic system is used for driving the concave plate clearance adjusting mechanism; the electric control system is used for controlling the hydraulic system to work; the concave plate gap adjusting mechanism comprises a driven crank, a driving crank, a pull rod and a displacement sensor; the electric control system comprises a dynamic torque sensor, a displacement sensor, a low-pass filter circuit, a PLC (programmable logic controller) and a computer; the hydraulic system comprises a hydraulic base station and a hydraulic working unit.

Description

Concave plate gap automatic regulating system based on feeding amount and threshing and separating device

Technical Field

The utility model belongs to the agricultural machine field, concretely relates to concave board clearance automatic regulating system based on feeding volume.

Background

In recent years, with the improvement of the mechanized harvesting level of corns in China, particularly the research and development of the corn kernel harvesting technology, the direct harvesting of the corn kernels becomes the development direction of the corn harvesting in China. The corn threshing and separating device is used as a main operation device for directly harvesting corn kernels, and the optimization and adjustment of working parameters of the corn threshing and separating device have important significance on threshing performance.

The clearance between the concave plates, namely the threshing clearance, is the distance between the top end of the threshing element and the concave plates, is one of the key working parameters of the threshing device, and has great influence on the grain crushing rate and the threshing performance. The difference of the threshing gaps causes the material flow density of corn ears and the like in the threshing chamber to change, the beating frequency of the threshing elements on the ears is changed, and the acting force between the ears and the concave plate and between the ears also changes, causing the change of the crushing rate and the non-threshing rate. At present foreign research and development earlier to threshing separation device, the earliest utility model goes out threshing gap manual regulation structure, and in recent years, partial expert scholars pass through hydraulic system and adjust the notch board clearance, and degree of automation is high, improves work efficiency. The research of domestic thresher is started late, and automatic integration is low, mostly is the concave plate clearance of independent control, and partial scholars are from automatic angle, through detecting cylinder rotational speed size, and then realize the automatic control in concave plate clearance. However, because the rotational speed of the drum has many factors, the gap between the concave plates cannot be accurately adjusted, and the actual threshing operation requirements are difficult to meet.

In order to overcome above shortcoming, the utility model discloses provide a notch board clearance automatic regulating system based on feeding volume to high moisture content maize, can realize satisfying the demand of threshing according to the size in the real-time automatically regulated notch board clearance of feeding volume size, reduce the percentage of damage, improve and take off clean rate.

SUMMERY OF THE UTILITY MODEL

In order to realize the purpose of the utility model, the following technical scheme is adopted to realize:

the utility model provides a threshing separation device concave clearance automatic regulating system based on feeding volume, includes concave clearance adjustment mechanism, electrical system and hydraulic system, threshing separation device includes threshing cylinder, top cap and concave, threshing cylinder is located the threshing chamber that comprises top cap and concave, wherein: the concave plate gap adjusting mechanism is used for adjusting the concave plate gap of the corn threshing and separating device; the hydraulic system is used for driving the concave plate clearance adjusting mechanism; the electric control system is used for controlling the hydraulic system to work; the concave plate gap adjusting mechanism comprises a driven crank, a driving crank and a pull rod; the electric control system comprises a dynamic torque sensor, a displacement sensor, a low-pass filter circuit, a PLC (programmable logic controller) and a computer; the hydraulic system comprises a hydraulic base station and a hydraulic working unit.

The system of (a), wherein: the two sides of the driving crank are respectively provided with a driven crank, one end of each driven crank and one end of each driving crank are hinged to the connecting rod on the top cover, the other end of each driven crank is hinged to one end of the pull rod, the other end of each pull rod is hinged to the concave plate, the other end of each driving crank is hinged to one end of the hydraulic cylinder, and the other end of each hydraulic cylinder is hinged to the concave plate.

The system of (a), wherein: the displacement sensor is a laser ranging sensor and is arranged at the top end of a telescopic rod of the hydraulic cylinder.

The system of (a), wherein: the PLC is internally provided with an A/D conversion module, a 5V power supply module, a dynamic torque sensor-feeding amount real-time monitoring module and a PID (proportion integration differentiation) adjusting algorithm module; the low-pass filter circuit is a multi-input multi-output circuit and is used for respectively transmitting a strain signal of the dynamic torque sensor and an electric signal of the displacement sensor to an A/D conversion module of the PLC, and the dynamic torque sensor-feeding amount real-time monitoring module is used for calculating an actual detection value of the feeding amount according to a digital signal of the strain signal of the dynamic torque sensor converted by the A/D conversion module; the PID algorithm adjusting module is used for automatically matching a proper concave plate gap adjusting range according to an actual detection value of the feeding amount and sending the adjusting amount to the proportional reversing valve; the computer is connected with the PLC through a bus.

The system of (a), wherein: the hydraulic base station comprises an electromagnetic directional valve, an oil return filter, an air filter, a liquid temperature liquid level meter, an air cooler, a plunger pump, a motor and a high-pressure filter.

The system of (a), wherein: the motor drives the plunger pump through the coupler, one end of the high-pressure filter is connected with the plunger pump through an oil pipe, and the other end of the high-pressure filter is connected with the electromagnetic directional valve.

The system of (a), wherein: the air filter, the liquid temperature liquid level meter and the air cooler are all externally connected in the hydraulic base station, wherein the air filter and the air cooler are used for cooling the hydraulic base station; the liquid temperature liquid level meter is used for detecting the liquid level height and the temperature of the oil tank.

The system of (a), wherein: the hydraulic base station further comprises an overflow valve, the overflow valve is connected to the outlet of the hydraulic base station in a bypassing mode, and an oil inlet of the electromagnetic directional valve is connected with an oil inlet of the overflow valve through a high-pressure oil pipe.

The system of (a), wherein: the hydraulic working unit comprises a hydraulic cylinder, a pressure measuring joint, a balance valve and a proportional reversing valve, oil outlets and oil outlets are formed in the proportional reversing valve, the balance valve and the hydraulic cylinder, and oil inlets and oil return ports of the proportional reversing valve are connected with the hydraulic pump; and the other oil inlet and outlet of the balance valve is connected with the upper oil inlet and outlet of the hydraulic cylinder.

The system of (a), wherein: the hydraulic cylinder is connected with the balance valve through a high-strength hydraulic pipe, a branch is led out from the high-strength hydraulic pipe, and a pressure measuring joint is installed.

A threshing and separating apparatus comprising a system as described in one of the above.

Drawings

FIG. 1 is a schematic view of the mechanical structure of the present invention;

fig. 2 is a schematic view of the displacement sensor of the present invention;

fig. 3 is a schematic structural view of the electric control system of the present invention;

FIG. 4 is a schematic diagram of the PID adjustment algorithm module of the present invention;

fig. 5 is a schematic structural diagram of the hydraulic system of the present invention;

fig. 6 is a schematic view of a hydraulic oil path flow diagram.

Wherein the reference numerals are:

1 threshing cylinder 2 head cover

3 driven crank and 4 driving crank

5 motor 6 dynamic torque sensor

7 pull rod 8 displacement sensor

9 hydraulic cylinder 10 concave plate

11 low-pass filter circuit 12A/D conversion module

1324V switching power supply 14 PLC controller

15 man-machine interface 16 balance valve

17 proportional reversing valve 18 PID algorithm adjusting module

195V power module 20 pressure measuring joint

21 displacement sensor range finding return circuit

23 dynamic torque sensor-feed rate real-time monitoring

24 automatic adjustment mode 25 manual adjustment mode

26-superposition overflow valve 27 electromagnetic directional valve

28 oil return filter 29 air cleaner

30 liquid level liquid thermometer 31 air cooler

32 plunger pump 33 motor

34 high pressure filter 35 pressure gauge

36 rack

o (k) expected value of gap between concave plates y (k) expected value of extension of hydraulic cylinder

e (k) deviation of expected value from actual value

u (k) PID calculated output value difference p (k) balance valve output value

h (t) actual output value of proportional directional control valve

s (k) actual detection of extension value of hydraulic cylinder

Detailed Description

The following describes the present invention in detail with reference to the accompanying fig. 1-5.

As shown in figure 1, figure 3 and figure 5, the automatic concave plate gap adjusting system based on the feeding amount can be used for a corn threshing and separating device, and mainly comprises a concave plate gap adjusting mechanism, an electric control system and a hydraulic system.

As shown in figure 1, the corn threshing and separating device comprises a threshing cylinder 1, a top cover 2, a driven crank 3, a driving crank 4, a motor 5, a dynamic torque sensor 6, a pull rod 7, a displacement sensor 8, a hydraulic cylinder 9 and a concave plate 10. The threshing cylinder 1 is located in a threshing chamber formed by a top cover 2 and a concave plate 10. The two ends of the dynamic torque sensor 6 are respectively connected with a threshing roller shaft and a motor shaft; the motor 5 drives the threshing cylinder 1 to rotate through the dynamic torque sensor 6, so that the real-time torque of the threshing cylinder 1 is measured, and the feeding amount is calculated. The concave plate gap adjusting mechanism comprises a driven crank 3, a driving crank 4, a pull rod 7 and a displacement sensor 8, wherein the driven crank 3 is arranged on each of the two sides of the driving crank 4, one end of each of the driven crank 3 and the driving crank 4 is hinged with a connecting rod on the top cover 2, the other end of each of the driven cranks 3 is hinged with one end of the pull rod 7, the other end of each of the pull rods 7 is hinged with the concave plate 10, the other end of each of the driving cranks 4 is hinged with one end of a hydraulic cylinder 9, and the other end of; the hydraulic cylinder 9 stretches and retracts to drive the driving crank 4 to rotate up and down, the driving crank 4 drives the driven cranks 3 at the two ends to rotate coaxially, the pull rod 7 moves up and down, and the concave plate gap is adjusted. As shown in fig. 2, the displacement sensor 8 is a laser distance measuring sensor, the displacement sensor 8 is installed at the top end of the telescopic rod of the hydraulic cylinder 9, and the displacement sensor 8 irradiates the cylinder wall of the hydraulic cylinder 9 through laser to measure the telescopic distance.

It should be understood by those skilled in the art that the above-mentioned corn threshing and separating device is only one specific application example of the automatic concave clearance adjusting system based on feeding amount, and of course, the automatic concave clearance adjusting system based on feeding amount of the present invention can also be applied to threshing and separating devices of other structures (transverse axial flow threshing device, tangential flow threshing device, etc.).

As shown in fig. 3 and 4, the electronic control system comprises a dynamic torque sensor 6, a displacement sensor 8, a low-pass filter circuit 11, a 24V switching power supply 13, a PLC controller 14 and a computer 15; the PLC 14 is internally provided with an A/D conversion module 12, a 5V power supply module 19, a dynamic torque sensor-feed amount real-time monitoring module 23 and a PID (proportion integration differentiation) adjusting algorithm module 18; the 24V power supply module 13 supplies power to the PLC 14 and the computer 15 at the same time; the 5V power supply module 19 supplies power to the low-pass filter circuit 11; wherein, the low-pass filter circuit 11 allows the signal lower than the cut-off frequency to pass, i.e. playing the role of anti-interference to the high-frequency noise, the low-pass filter circuit 11 is a multi-input multi-output circuit, and is used for respectively transmitting the strain signal of the dynamic torque sensor 6 and the electric signal of the displacement sensor 8 to the A/D conversion module 12 of the PLC 14, the dynamic torque sensor-feeding amount real-time monitoring module 23 calculates the actual detection value of the feeding amount according to the digital signal of the strain signal of the dynamic torque sensor 6 converted by the A/D conversion module 12 (the feeding amount is the corn quality entering the threshing device per second, a certain approximate linear relation exists between the torque magnitude of the threshing cylinder 1 and the feeding amount, when the corn enters the threshing chamber, the torque magnitude of the threshing cylinder 1 will change, the dynamic torque sensor 6 will measure the torque magnitude of the threshing cylinder 1, the signal of the torque is transmitted to a real-time monitoring module 23, the real-time monitoring module 23 automatically calculates the feeding amount according to the relation, a PID algorithm adjusting module 18 of the PLC 14 can automatically match a proper concave plate gap adjusting range according to the actual detection value of the feeding amount to adapt to the real-time change of the feeding amount, and can calculate the size of the concave plate gap according to the fitting relation of the following formula according to the known feeding amount, wherein o (K) is 1.5w +39.6, and the o (K) is the expected value of the concave plate gap, mm, w is the feeding amount, and kg/s. (for example, when the feeding amount is 5-6 kg/s, the gap between the concave plates is 48mm, when the feeding amount is 7-8 kg/s, the gap between the concave plates is 51mm, along with the increase of the feeding amount, the gap between the concave plates can be reasonably increased within a certain range), and meanwhile, the displacement sensor 8 detects the actual stretching amount of the hydraulic cylinder in real time, and continuously corrects the error through the PID algorithm adjusting module 18, so that the adjustment of the gap between the concave plates is more timely and accurate. Then, the PLC 14 transmits the output signal to a proportional reversing valve 17 and transmits the output signal to the bidirectional hydraulic cylinder 9 through a balance valve 16; the hydraulic cylinder 9 is a bidirectional hydraulic cylinder, and the balance valve 16 can keep the telescopic rod of the hydraulic cylinder 9 at a preset position. The above is the auto-adjustment mode. The manual adjustment mode is similar to the above process, but the preset value of the gap of the concave plate is input through the computer 15, and the hydraulic cylinder 9 is controlled by the PLC 14 to extend to the preset position, so as to realize the manual adjustment of the gap of the concave plate. The computer 15 is connected with the PLC 14 through a CAN bus, and CAN display the torque of the threshing cylinder 1, the feeding amount and the gap of the concave plate in real time and select the control mode (automatically and manually).

As shown in fig. 1, 2 and 5, the hydraulic system comprises a hydraulic cylinder 9, a pressure measuring joint 20, a balance valve 16, a proportional reversing valve 17, a superposition overflow valve 26, an electromagnetic reversing valve 27, an oil return filter 28, an air filter 29, a liquid level liquid thermometer 30, an air cooler 31, a plunger pump 32, a motor 33, a high-pressure filter 34 and a pressure gauge 35 which are connected in sequence; the upper end of the hydraulic cylinder 9 is connected with the driving crank 4, the lower end is hinged with the frame 36, and the size of the threshing gap of the concave plate 10 is adjusted according to the feeding amount. The signal input end of the proportional reversing valve 17 is connected with the output end of a PID adjusting algorithm module 18 in the PLC 14, and the proportional reversing valve 17 is controlled by the PWM wave output of the PID adjusting algorithm module 18 of the PLC 14 so as to control the action of the hydraulic cylinder 9 and finally act on the concave plate 10. As shown in fig. 6, the hydraulic oil flow path is labeled with arrows for ease of description and understanding. The hydraulic system is divided into two parts: the hydraulic base station and the hydraulic working unit. The hydraulic base station is mainly used for supplying oil to working components such as a hydraulic cylinder and the like. The hydraulic pressure basic station includes solenoid directional valve 27, oil return filter 28, air cleaner 29, liquid temperature level gauge 30, air cooler 31, plunger pump 32, motor 33, high pressure cleaner 34, the hydraulic pressure basic station main part is a hydraulic tank (not mark in the picture), external various parts, and wherein motor 33 passes through shaft coupling drive plunger pump 32 to make the interior oil of hydraulic tank at the oil circuit inner loop flow, wherein high pressure cleaner 34 passes through oil piping connection with plunger pump 32, and the oil that flows out from plunger pump 32 carries out first filtration, makes things convenient for clean oil to get into subsequent working component. The hydraulic oil passing through the high-pressure filter 34 flows to the electromagnetic directional valve 27 (corresponding to a directional switching valve, the hydraulic oil circulates inside the hydraulic base station in the open state, and the hydraulic oil flows to the working portion in the closed state) in two directions, and the relief valve 26 is bypassed to the outlet of the hydraulic base station. An oil inlet P of the electromagnetic directional valve 27 is connected with an oil inlet of the overflow valve 26 through a high-pressure oil pipe, the left side of the overflow valve 26 is an oil inlet, and the right side of the overflow valve 26 is an oil return port. The return oil filter 28 is arranged on a return oil pipeline at the tail end of the system, and when the hydraulic oil circulates in the hydraulic base station or flows back from the working part, the return oil filter 28 is used for filtering the returned hydraulic oil for the second time, and finally the hydraulic oil returns to the oil tank. The air filter 29, the liquid temperature liquid level meter 30 and the air cooler 31 are externally connected in the hydraulic base station, wherein the air filter 29 and the air cooler 31 are used for cooling the hydraulic base station, namely, the air cooler cools the hydraulic base station (the hydraulic base station generates a large amount of heat during working, and the working performance and safe operation are seriously affected by too high oil temperature). The liquid temperature liquid level meter 30 detects the liquid level height and the temperature of the oil tank. As described above, when the electromagnetic directional valve 27 is closed, the hydraulic oil flows to the working portion and first flows through the electromagnetic directional valve 17, which is a left-right opening/closing type electromagnetic valve, and the closing and opening of the valve are realized by controlling the electromagnet. The left valve and the right valve are matched in opening and closing, so that oil pressure difference is generated at two ends of a push rod of the hydraulic cylinder, and the hydraulic cylinder stretches and retracts. The overflow valve 26 is a protection valve to prevent the precise electromagnetic valve from being damaged by too large oil pressure, and the oil can be automatically discharged after the oil pressure exceeds a safety value. The hydraulic working unit comprises a hydraulic cylinder 9, a pressure measuring joint 20, a balance valve 16 and a proportional reversing valve 17, oil outlets and oil outlets are arranged on the hydraulic cylinder 9 of the proportional reversing valve 17 and the balance valve 16, as shown in fig. 5, the proportional reversing valve 17 is a three-position four-way valve, wherein P, T are respectively an oil inlet and an oil return port, and the two are connected with the plunger pump 32. An oil port A, B of the proportional directional valve 17 is respectively connected with a lower oil inlet and outlet of the hydraulic cylinder 9 and an oil inlet and outlet of the balance valve 16, wherein the balance valve 16 has two oil inlets and outlets, and the other oil inlet and outlet of the balance valve 16 is connected with an upper oil inlet and outlet of the hydraulic cylinder 9. The pressure tap 20 is a pipe joint for connection between the pipe and the hydraulic component. The hydraulic cylinder 9 is connected with the balance valve 16 through a high-strength hydraulic pipe, a branch is led out from the high-strength hydraulic pipe by a pressure measuring joint 20, and the pressure measuring joint 20 is installed.

As shown in FIG. 4, the schematic diagram of the PID adjustment algorithm module is divided into two modes, namely an automatic adjustment mode 24 and a manual adjustment mode 25. In the automatic adjustment mode, the dynamic torque sensor-feed amount real-time monitoring module 23 automatically calculates the corresponding feed amount according to the torque of the threshing cylinder 1, preselects the expected value o (k) of the gap between the concave plates based on the size of the feed amount (for example, the optimal gap between the concave plates with the feed amount of 10kg/s is 55mm, when the feed amount is 9-10 kg/s, the gap matching value of the concave plates is 55mm), and the feed amount and the gap between the concave plates are in an approximate positive correlation linear relationship, wherein: the torque sensor detects the torque of the threshing cylinder shaftThe feeding amount is calculated by the following fitting relation formula: m ═ k₀Rq, where M is the drum shaft torque, N/M, k₀-a constant; typically, take 8, R-roller radius, m; q-feed, kg/s. The expected telescopic value y (k) of the hydraulic cylinder can be obtained through a relation function of the size of the gap of the concave plate and the telescopic quantity of the hydraulic cylinder, and the fitting relation of the gap of the concave plate and the telescopic quantity of the hydraulic cylinder is as follows: s-0.1774 o (k) +37.223, where s is the amount of extension and retraction of the hydraulic cylinder, mm, o (k) -desired value of the gap between the platens, mm.

The PID adjusting algorithm module 18 performs corresponding operation processing according to the extension expected value y (k) of the hydraulic cylinder and the deviation e (k) of the real-time feedback actual detection value y (k) of the displacement sensor distance measuring loop 21 (namely the displacement sensor 8), namely, the two values are subjected to subtraction calculation, the difference value is the deviation e (k), then the output value of an adjusting signal is input to the proportional directional valve 17 according to the deviation e (k) to control the hydraulic output quantity, finally the hydraulic cylinder 9 is controlled by the balance valve 16 to perform corresponding action, so that the size of the gap between the concave plates is changed, and the extension actual value of the hydraulic cylinder is detected by the displacement sensor distance measuring loop 21 to form a closed loop, so that the gap between the concave plates is adjusted and maintained within a preset value. Specifically, the method comprises the following steps: the proportional reversing valve 17 is used for controlling the flow and the flow direction of the hydraulic system through a proportional electromagnet. The PLC 14 transmits an output value for controlling the extension or the shortening of the hydraulic cylinder to the proportional reversing valve 17 in a PWM wave signal mode, an electromagnet in the proportional reversing valve 17 can control the size of a valve opening according to a received PWM signal, the expansion value is large, the required flow is large, the valve adjustment can be correspondingly large, the valve is just started to be large, and when the valve is closer to the expansion preset value of the hydraulic cylinder, the valve can be reduced, the flow is reduced, the slow adjustment is realized, and the corresponding precision is ensured. The balancing valve 16 functions as: the hydraulic cylinder 9 used in the system is a bidirectional hydraulic cylinder (generally, the bidirectional hydraulic cylinder is driven by bidirectional hydraulic pressure and can reciprocate at a constant speed) and is used for adjusting the relative balance of the pressures on two sides of the hydraulic cylinder 9 so as to keep the hydraulic cylinder at a certain position. If no balance valve is arranged, the telescopic rod of the hydraulic cylinder cannot be kept at a fixed position, and the gap of the concave plate cannot be kept within a certain range. As mentioned above, the cooperation of the three is that the proportional directional valve 17 controls the flow and direction of the oil, which flows to the hydraulic cylinder 9 through the balance valve 16. Thereby controlling the extension or retraction of the hydraulic cylinders and controlling their size. The manual adjustment mode is similar to the automatic adjustment mode, the expected value o (K) of the gap of the concave plate is manually input in the manual adjustment mode through the human-computer interface 15, the control system calculates the expansion amount of the hydraulic cylinder 9 through programming, the adjustment of the gap of the concave plate is achieved, and the gap of the concave plate cannot be automatically adjusted along with the feeding amount.

The working process of the utility model is as follows:

firstly, an automatic mode or a manual mode is selected through the computer 15, the automatic adjustment mode is directly clicked to start, the PLC controller 14 can automatically start the dynamic torque sensor 6 and the displacement sensor 8, the dynamic torque sensor 6 can transmit the torque of the threshing cylinder to the PLC controller 14 in a voltage signal mode, the PLC controller 14 obtains the feeding amount through programming calculation, the feeding amount is automatically matched with the size of the gap of the concave plate, the PWM signal output value u (k) of the PID algorithm adjustment module 18 is transmitted to the proportional reversing valve 17, the expansion and contraction of the hydraulic cylinder 9 are controlled through the balance valve 16, the hydraulic cylinder 9 expands and contracts to drive the driving crank 4 to rotate up and down, the driving crank 4 drives the driven cranks 3 at two ends to rotate coaxially, the pull rod 7 moves up and down, the adjustment of the gap of the concave plate is realized, the crushing rate and the non-threshing rate in the corn threshing separation process are reduced, and the threshing operation quality and. The manual adjusting mode directly inputs a preset value through a human-computer interface 15, and the hydraulic cylinder 9 is regulated and controlled by the PLC 14 to realize the adjustment of the gap of the concave plate, but the gap of the concave plate cannot be adjusted in real time along with the feeding amount.

In the period, the PLC continuously converts the electric signals collected by the displacement sensor 8 in real time into the current telescopic detection value of the hydraulic cylinder 9 to be compared with the telescopic preset value of the hydraulic cylinder 9, the PID adjusting algorithm module controls the hydraulic output quantity of the proportional reversing valve according to the deviation value to enable the hydraulic output quantity to reach the preset length, the hydraulic pressure acts on the concave plate 10 under the action of the push rod of the hydraulic cylinder, and finally the purpose of adjusting and maintaining the expected value of the gap of the concave plate is achieved.

The above is only the embodiment of the present invention, not the limitation of the protection scope of the present invention, all the equivalent structures or equivalent processes of the content of the specification and the drawings are used for conversion, or directly or indirectly applied to other related technical fields, and the same principle is included in the protection scope of the present invention.

Claims (10)

1. The utility model provides a threshing separation device concave clearance automatic regulating system based on feeding volume, includes concave clearance adjustment mechanism, electrical system and hydraulic system, threshing separation device includes threshing cylinder, top cap and concave, threshing cylinder is located the threshing chamber that comprises top cap and concave, its characterized in that: the concave plate gap adjusting mechanism is used for adjusting the concave plate gap of the corn threshing and separating device; the hydraulic system is used for driving the concave plate clearance adjusting mechanism; the electric control system is used for controlling the hydraulic system to work; the concave plate gap adjusting mechanism comprises a driven crank, a driving crank and a pull rod; the electric control system comprises a dynamic torque sensor, a displacement sensor, a low-pass filter circuit, a PLC (programmable logic controller) and a computer; the hydraulic system comprises a hydraulic base station and a hydraulic working unit.

2. The feed-based automatic concave-plate gap adjusting system of a threshing-separating device according to claim 1, characterized in that: the two sides of the driving crank are respectively provided with a driven crank, one end of each driven crank and one end of each driving crank are hinged to the connecting rod on the top cover, the other end of each driven crank is hinged to one end of the pull rod, the other end of each pull rod is hinged to the concave plate, the other end of each driving crank is hinged to one end of the hydraulic cylinder, and the other end of each hydraulic cylinder is hinged to the concave plate.

3. The feed-based automatic concave-plate gap adjusting system of a threshing-separating device according to claim 1, characterized in that: the displacement sensor is a laser ranging sensor and is arranged at the top end of a telescopic rod of the hydraulic cylinder.

4. The feed-based automatic concave-plate gap adjusting system of a threshing-separating device according to claim 1, characterized in that: the hydraulic base station comprises an electromagnetic directional valve, an oil return filter, an air filter, a liquid temperature liquid level meter, an air cooler, a plunger pump, a motor and a high-pressure filter.

5. The feed-based automatic concave-plate gap adjusting system of a threshing-separating device according to claim 4, characterized in that: the motor drives the plunger pump through the coupler, one end of the high-pressure filter is connected with the plunger pump through an oil pipe, and the other end of the high-pressure filter is connected with the electromagnetic directional valve.

6. The feed-based automatic concave-plate gap adjusting system of a threshing-separating device according to claim 4, characterized in that: the air filter, the liquid temperature liquid level meter and the air cooler are all externally connected in the hydraulic base station, wherein the air filter and the air cooler are used for cooling the hydraulic base station; the liquid temperature liquid level meter is used for detecting the liquid level height and the temperature of the oil tank.

7. The feed-based automatic concave-plate gap adjusting system of a threshing-separating device according to claim 4, characterized in that: the hydraulic base station further comprises an overflow valve, the overflow valve is connected to the outlet of the hydraulic base station in a bypassing mode, and an oil inlet of the electromagnetic directional valve is connected with an oil inlet of the overflow valve through a high-pressure oil pipe.

8. The feed-based automatic concave-plate gap adjusting system of a threshing-separating device according to claim 1, characterized in that: the hydraulic working unit comprises a hydraulic cylinder, a pressure measuring joint, a balance valve and a proportional reversing valve, oil outlets and oil outlets are formed in the proportional reversing valve, the balance valve and the hydraulic cylinder, and oil inlets and oil return ports of the proportional reversing valve are connected with the hydraulic pump; and the other oil inlet and outlet of the balance valve is connected with the upper oil inlet and outlet of the hydraulic cylinder.

9. The feed-based automatic concave-plate gap adjusting system of threshing-separating device according to claim 8, characterized in that: the hydraulic cylinder is connected with the balance valve through a high-strength hydraulic pipe, a branch is led out from the high-strength hydraulic pipe, and a pressure measuring joint is installed.

10. A threshing and separating device characterized by comprising a feed-based threshing and separating device concave gap automatic adjusting system according to any one of claims 1 to 9.

Images