CN214555271U - Ultrasonic vibration sieve circuit control device - Google Patents

Abstract

The utility model discloses an ultrasonic vibration sieve circuit control device, including the master switch, microprocessor and host computer, the car end electric connection that sells goods of master switch has protection module, and protection module's output electric connection has conversion module, conversion module's output electric connection is on microprocessor's input, microprocessor's output electric connection has the chopper, and the output electric connection of chopper has voltage sampling module, voltage sampling module's output electric connection has servo driver, and servo driver output electric connection has current sampling module and servo motor. The utility model discloses a feedback module can real-time supervision shale shaker's state, judges whether the shale shaker is in overload state through pressure and the vibration frequency that the measurement shale shaker screen frame bore to pass through display and communication module with data in real time and give the user with the monitoring data transmission, thereby make the user can in time adjust when the device transships, avoid serious consequence.

Description

Ultrasonic vibration sieve circuit control device

Technical Field

The utility model relates to an ultrasonic vibration sieve technical field especially relates to an ultrasonic vibration sieve circuit control device.

Background

The ultrasonic vibration sieve converts 220v, 50HZ or 110v, 60HZ electric energy into 38KHZ high-frequency electric energy, inputs the ultrasonic transducer, changes the high-frequency electric energy into 38KHZ mechanical vibration, thereby achieving the purposes of high-efficiency sieving and cleaning.

The existing circuit control device of the ultrasonic vibration screen is not provided with a feedback system generally and only has a common power-on and power-off function, when the material quality in the vibration screen is too large due to improper operation, the alarm cannot be given, and the loss of the vibration screen is accelerated and even an accident is caused when the vibration screen runs under an overload state for a long time. Therefore, it is desirable to design a circuit control device for an ultrasonic vibration sieve to solve the above problems.

Disclosure of Invention

The utility model aims at solving the problem that the prior art does not have a feedback system, only has a common on-off function and an unable alarm defect, and provides an ultrasonic vibration sieve circuit control device.

In order to achieve the above purpose, the utility model adopts the following technical scheme: a circuit control device of an ultrasonic vibration sieve comprises a main switch, a microprocessor and an upper computer, wherein the vending vehicle end of the main switch is electrically connected with a protection module, the output end of the protection module is electrically connected with a conversion module, the output end of the conversion module is electrically connected with the input end of a microprocessor, the output end of the microprocessor is electrically connected with a chopper, the output end of the chopper is electrically connected with a voltage sampling module, the output end of the voltage sampling module is electrically connected with a servo driver, the output end of the servo driver is electrically connected with a current sampling module and a servo motor, one end of the current sampling module far away from the servo driver is electrically connected with the input end of the voltage sampling module, the servo motor is provided with a feedback module through a bolt, and the output end of the feedback module is electrically connected to one input end of the microprocessor.

The key concept of the technical scheme is as follows: through the feedback module who sets up, the state of feedback module can real-time supervision shale shaker, and pressure and the vibration frequency that bear through measuring the shale shaker screen frame judge whether be in overload state the shale shaker to pass through display and communication module with data in real time and give the user with monitoring data transmission, thereby make the user can in time adjust when the device transships, avoid serious consequence.

Further, the feedback module comprises a pressure sensor and a vibration pickup electrically connected to the output end of the pressure sensor, the pressure sensor and the vibration pickup are both mounted on the servo motor through bolts, and the output end of the vibration pickup is electrically connected to an input end of the microprocessor.

Furthermore, an input/output end of the microprocessor is electrically connected with a display starting module, an input/output end of the display driving module is electrically connected with a display, and a time setting module and an operation input module are connected in parallel in the display.

Furthermore, an input/output end of the microprocessor is electrically connected with a communication module, and the communication module is connected with the upper computer through a network.

Furthermore, an independent power supply circuit is connected in parallel with the microprocessor through the output end of the conversion module, a clock circuit is electrically connected to the output end of the independent power supply circuit, and the output end of the clock circuit is electrically connected to one input end of the microprocessor.

Further, the protection module includes electric leakage circuit breaker, fuse and lightning protection device, lightning protection device and electric leakage circuit breaker connect in parallel on the output of master switch, and fuse electric connection is on electric leakage circuit breaker's output, the output electric connection of fuse is on the input of conversion module.

Further, the conversion module includes a voltage reduction module, a rectification module, a voltage stabilization module and a filtering module, an input end of the voltage reduction module is electrically connected with an output end of the fuse, an input end of the rectification module is electrically connected with an output end of the voltage reduction module, an input end of the voltage stabilization module is electrically connected with an output end of the rectification module, an input end of the filtering module is electrically connected with an output end of the voltage stabilization module, and an output end of the filtering module is electrically connected with an input end of the microprocessor.

The utility model has the advantages that:

1. through the feedback module who sets up, the state of feedback module can real-time supervision shale shaker, and pressure and the vibration frequency that bear through measuring the shale shaker screen frame judge whether be in overload state the shale shaker to pass through display and communication module with data in real time and give the user with monitoring data transmission, thereby make the user can in time adjust when the device transships, avoid serious consequence.

2. Through the clock circuit and the time setting module, the clock circuit and the time setting module can provide a timing function for the device, so that the device is timed to be switched on or switched off, or is stopped for a period of time when working, and overheating of the device caused by long-time continuous working is avoided.

3. Through the communication module who sets up, communication module can be connected with the host computer to make the data of reciprocating sieve can upload to the host computer and show in real time, and can make the user control the reciprocating sieve through the host computer, can the person of facilitating the use carry out unified management to a large amount of reciprocating sieves.

Drawings

Fig. 1 is a schematic structural view of a circuit control device of an ultrasonic vibration sieve according to the present invention;

fig. 2 is a schematic structural diagram of a protection module of the circuit control device of the ultrasonic vibration sieve according to the present invention;

fig. 3 is a schematic structural diagram of a conversion module of the circuit control device of the ultrasonic vibration sieve of the present invention;

fig. 4 is the utility model provides an ultrasonic vibration sieve circuit control device's feedback module structure sketch map.

In the figure: the device comprises a main switch 1, a protection module 2, a conversion module 3, a microprocessor 4, a chopper 5, a voltage sampling module 6, a servo driver 7, a current sampling module 8, a servo motor 9, a feedback module 10, an independent power supply circuit 11, a clock circuit 12, a display starting module 13, a display 14, a time setting module 15, an operation input module 16, a leakage circuit breaker 17, a fuse 18, a lightning arrester 19, a voltage reduction module 20, a rectification module 21, a filtering module 22, a voltage stabilizing module 23, a pressure sensor 24, a vibration pickup 25, an upper computer 26 and a communication module 27.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1 to 4, an ultrasonic vibration sieve circuit control device includes a main switch 1, a microprocessor 4 and an upper computer, wherein a vending cart end of the main switch 1 is electrically connected with a protection module 2, an output end of the protection module 2 is electrically connected with a conversion module 3, an output end of the conversion module 3 is electrically connected with an input end of the microprocessor 4, an output end of the microprocessor 4 is electrically connected with a chopper 5, the chopper 5 is used for controlling a voltage and a current delivered to a servo driver 7, an output end of the chopper 5 is electrically connected with a voltage sampling module 6, the voltage sampling module 6 is used for monitoring a voltage, an output end of the voltage sampling module 6 is electrically connected with the servo driver 7, an output end of the servo driver 7 is electrically connected with a current sampling module 8 and a servo motor 9, the current sampling module 8 is used for monitoring a current, one end of the current sampling module 8 far away from the servo driver 7 is electrically connected with an input end of the voltage sampling module 6, the servo motor 9 is provided with a feedback module 10 through a bolt, and the output end of the feedback module 10 is electrically connected to one input end of the microprocessor 4.

As can be seen from the above description, the present invention has the following advantages: through the feedback module 10 that sets up, feedback module 10 can real-time supervision shale shaker's state, judges whether the shale shaker is in overload state through pressure and the vibration frequency that the measurement shale shaker screen frame bore to pass through display 14 and communication module 27 with data in real time and give the user with monitoring data transmission, thereby make the user can in time adjust when the device transships, avoid serious consequence.

Further, the feedback module 10 includes a pressure sensor 24 and a vibration pickup 25 electrically connected to an output end of the pressure sensor 24, the pressure sensor 24 and the vibration pickup 25 are both mounted on the servo motor 9 by bolts, and an output end of the vibration pickup 25 is electrically connected to an input end of the microprocessor 4.

Further, one input/output end of the microprocessor 4 is electrically connected with a display starting module 13, an input/output end of the display driving module 13 is electrically connected with a display 14, the display 14 is used for displaying data of the device, and a time setting module 15 and an operation input module 16 are connected in parallel inside the display.

Further, an input/output end of the microprocessor 4 is electrically connected with a communication module 27, the communication module 27 is used for sending the message to the upper computer 26, and the communication module 27 and the upper computer 26 are connected with each other through a network.

Furthermore, the output end of the conversion module 3 is electrically connected to the microprocessor 4 in parallel to form an independent power supply circuit 11, the independent power supply circuit 11 can continue to operate when the device is in standby, the output end of the independent power supply circuit 11 is electrically connected to the clock circuit 12, the clock circuit 12 is used for timing, and the output end of the clock circuit 12 is electrically connected to one input end of the microprocessor 4.

Further, protection module 2 includes residual current circuit breaker 17, fuse 18 and lightning protection device 19, and residual current circuit breaker 17, fuse 18 and lightning protection device 19 are used for protecting circuit control device, and lightning protection device 19 and residual current circuit breaker 17 connect in parallel on the output of master switch 1, and fuse 18 electric connection is on residual current circuit breaker 17's output, and fuse 18's output electric connection is on conversion module 3's input.

Further, the conversion module 3 includes a voltage-reducing module 20, a rectifying module 21, a voltage-stabilizing module 22 and a filtering module 23, the voltage-reducing module 20, the rectifying module 21, the voltage-stabilizing module 22 and the filtering module 23 are used for converting alternating current into direct current, the input end of the voltage-reducing module 20 is electrically connected with the output end of the fuse 18, the input end of the rectifying module 21 is electrically connected with the output end of the voltage-reducing module 20, the input end of the voltage-stabilizing module 22 is electrically connected with the output end of the rectifying module 21, the input end of the filtering module 23 is electrically connected with the output end of the voltage-stabilizing module 22, and the output end of the filtering module 23 is electrically connected with an input end of the microprocessor 4.

By adopting the clock circuit 12 and the time setting module 15, the clock circuit 12 and the time setting module 15 can provide a timing function for the device, so that the device can be switched on and off at regular time or stopped for a period of time when working for a period of time, thereby avoiding overheating of the device caused by long-time continuous working; the communication module 27 that sets up, communication module 27 can be connected with host computer 26 to make the data of reciprocating sieve can upload to host computer 26 and show in real time, and can make the user control the reciprocating sieve through host computer 26, can the person of facilitating the use carry out unified management to a large amount of reciprocating sieves.

In the following, some preferred embodiments or application examples are listed to help those skilled in the art to better understand the technical content of the present invention and the technical contribution of the present invention to the prior art:

example 1

A circuit control device of an ultrasonic vibration sieve comprises a main switch 1, a microprocessor 4 and an upper computer, wherein a vending cart end of the main switch 1 is electrically connected with a protection module 2, an output end of the protection module 2 is electrically connected with a conversion module 3, an output end of the conversion module 3 is electrically connected with an input end of the microprocessor 4, an output end of the microprocessor 4 is electrically connected with a chopper 5, the chopper 5 is used for controlling voltage and current transmitted to a servo driver 7, an output end of the chopper 5 is electrically connected with a voltage sampling module 6, the voltage sampling module 6 is used for monitoring voltage, an output end of the voltage sampling module 6 is electrically connected with the servo driver 7, an output end of the servo driver 7 is electrically connected with a current sampling module 8 and a servo motor 9, the current sampling module 8 is used for monitoring current, one end of the current sampling module 8, which is far away from the servo driver 7, is electrically connected with an input end of the voltage sampling module 6, the servo motor 9 is provided with a feedback module 10 through a bolt, and the output end of the feedback module 10 is electrically connected to one input end of the microprocessor 4.

Wherein, the feedback module 10 comprises a pressure sensor 24 and a vibration pickup 25 electrically connected to the output end of the pressure sensor 24, the pressure sensor 24 and the vibration pickup 25 are both mounted on the servo motor 9 by bolts, and the output end of the vibration pickup 25 is electrically connected to one input end of the microprocessor 4; one input/output end of the microprocessor 4 is electrically connected with a display starting module 13, the input/output end of the display driving module 13 is electrically connected with a display 14, the display 14 is used for displaying data of the device, and a time setting module 15 and an operation input module 16 are connected in parallel inside the display; one input/output end of the microprocessor 4 is electrically connected with a communication module 27, the communication module 27 is used for sending messages to the upper computer 26, and the communication module 27 and the upper computer 26 are connected with each other through a network; the output end of the conversion module 3 is electrically connected with the independent power supply circuit 11 in parallel with the microprocessor 4, the independent power supply circuit 11 can continue to operate when the device is in a standby state, the output end of the independent power supply circuit 11 is electrically connected with the clock circuit 12, the clock circuit 12 is used for timing, and the output end of the clock circuit 12 is electrically connected with one input end of the microprocessor 4; the protection module 2 comprises a leakage circuit breaker 17, a fuse 18 and a lightning protector 19, the leakage circuit breaker 17, the fuse 18 and the lightning protector 19 are used for protecting the circuit control device, the lightning protector 19 and the leakage circuit breaker 17 are connected in parallel to the output end of the main switch 1, the fuse 18 is electrically connected to the output end of the leakage circuit breaker 17, and the output end of the fuse 18 is electrically connected to the input end of the conversion module 3; conversion module 3 includes step-down module 20, rectifier module 21, voltage stabilizing module 22 and filter module 23, step-down module 20, rectifier module 21, voltage stabilizing module 22 and filter module 23 are used for turning into the direct current with the alternating current, the input of step-down module 20 and the output electric connection of fuse 18, rectifier module 21's input electric connection is on step-down module 20's output, and voltage stabilizing module 22's input electric connection is on rectifier module 21's output, filter module 23's input electric connection is on voltage stabilizing module 22's output, and filter module 23's output electric connection is on a microprocessor 4's an input.

The working principle is as follows: when the vibrating screen is used, an operator firstly switches on an input power supply of the device, then turns on the main switch 1, then operates the input module 16 to set the device, the device is turned on through the operation input module 16, then the vibrating screen is turned on and works, in the working process, the pressure sensor 24 and the vibration pickup 25 can monitor the pressure and the vibration frequency borne by the screen body of the vibrating screen in real time and feed data back to the microprocessor 4, meanwhile, the voltage sampling module 6 and the current sampling module 8 feed back circuit voltage and current data to the microprocessor 4, the microprocessor 4 controls the circuit voltage and current through the chopper 5 according to the data to control the frequency and the amplitude of the vibrating screen, so that the screening effect is optimal, when the screen body of the vibrating screen is overloaded, the microprocessor 4 controls the display 14 through the display driving module 13 to give an alarm, and simultaneously transmits abnormal information to the upper computer 26 through the communication module 12, the user is notified.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (7)

1. The utility model provides an ultrasonic vibration sieve circuit control device, includes master switch (1), microprocessor (4) and host computer, its characterized in that, the car end electric connection of selling goods of master switch (1) has protection module (2), and the output electric connection of protection module (2) has conversion module (3), the output electric connection of conversion module (3) is on the input of microprocessor (4), the output electric connection of microprocessor (4) has chopper (5), and the output electric connection of chopper (5) has voltage sampling module (6), the output electric connection of voltage sampling module (6) has servo driver (7), and servo driver (7) output electric connection has current sampling module (8) and servo motor (9), the one end electric connection that servo driver (7) were kept away from in current sampling module (8) is on the input of voltage sampling module (6), the servo motor (9) is provided with a feedback module (10) through a bolt, and the output end of the feedback module (10) is electrically connected to one input end of the microprocessor (4).

2. An ultrasonic vibration screen circuit control apparatus as claimed in claim 1, wherein the feedback module (10) comprises a pressure sensor (24) and a vibration pickup (25) electrically connected to an output end of the pressure sensor (24), the pressure sensor (24) and the vibration pickup (25) are both mounted on the servo motor (9) by bolts, and an output end of the vibration pickup (25) is electrically connected to an input end of the microprocessor (4).

3. The circuit control device of the ultrasonic vibration screen is characterized in that a display starting module (13) is electrically connected to one input and output end of the microprocessor (4), a display (14) is electrically connected to the input and output end of the display driving module (13), and a time setting module (15) and an operation input module (16) are connected in parallel inside the display.

4. The circuit control device of the ultrasonic vibration screen according to claim 1, wherein a communication module (27) is electrically connected to one input/output end of the microprocessor (4), and the communication module (27) and the upper computer (26) are connected with each other through a network.

5. The circuit control device of the ultrasonic vibration sieve as claimed in claim 1, wherein the output end of the conversion module (3) is electrically connected with the microprocessor (4) in parallel to form an independent power supply circuit (11), the output end of the independent power supply circuit (11) is electrically connected with a clock circuit (12), and the output end of the clock circuit (12) is electrically connected with an input end of the microprocessor (4).

6. An ultrasonic vibration screen circuit control device according to claim 1, characterized in that, the protection module (2) includes an earth leakage breaker (17), a fuse (18) and a lightning arrester (19), the lightning arrester (19) and the earth leakage breaker (17) are connected in parallel on the output of the main switch (1), and the fuse (18) is electrically connected on the output of the earth leakage breaker (17), the output of the fuse (18) is electrically connected on the input of the conversion module (3).

7. An ultrasonic vibration sieve circuit control device according to claim 6, wherein the conversion module (3) comprises a voltage reduction module (20), a rectification module (21), a voltage stabilization module (22) and a filtering module (23), an input end of the voltage reduction module (20) is electrically connected with an output end of the fuse (18), an input end of the rectification module (21) is electrically connected with an output end of the voltage reduction module (20), an input end of the voltage stabilization module (22) is electrically connected with an output end of the rectification module (21), an input end of the filtering module (23) is electrically connected with an output end of the voltage stabilization module (22), and an output end of the filtering module (23) is electrically connected with an input end of the microprocessor (4).

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