CN111215310A

CN111215310A - Multi-gear ultrasonic generation control acquisition electric appliance cabinet

Info

Publication number: CN111215310A
Application number: CN202010030464.2A
Authority: CN
Inventors: 尤磊; 于保华; 葛羿麟; 王根; 段宇辉; 康茜
Original assignee: Hangzhou Dianzi University
Current assignee: Hangzhou Dianzi University
Priority date: 2020-01-13
Filing date: 2020-01-13
Publication date: 2020-06-02

Abstract

The invention belongs to the technical field of intelligent control systems, and particularly relates to a multi-gear ultrasonic generation control acquisition electric appliance cabinet which comprises an upper layer part and a lower layer part, wherein the upper layer part is used for arranging an electric control system, and the lower layer part is used for installing an ultrasonic generator; the electric control system comprises an air switch, a data acquisition control module, a digital quantity output module, an analog quantity input module, a frequency counting module, a relay-contactor control module, a temperature transmitter, a voltage transmitter, a current transmitter, a voltage-stabilized power supply and a terminal block. The multi-gear ultrasonic generation control acquisition electric appliance cabinet disclosed by the invention adopts the idea of easiness in operation and installation, realizes the integration of a control acquisition system in the electric appliance cabinet, can realize remote monitoring and control, improves the control efficiency, is convenient for development of matched electrical and control design work of a machine tool, improves the stability and reliability of the electric appliance cabinet, and reduces the cost investment.

Description

Multi-gear ultrasonic generation control acquisition electric appliance cabinet

Technical Field

The invention belongs to the technical field of intelligent control systems, and particularly relates to a multi-gear ultrasonic generation control acquisition electric appliance cabinet.

Background

The mainstream processing mode of the core material of the composite structure similar to the Nomex honeycomb is high-speed milling, and with the research, the high-speed milling process and equipment are continuously improved, but the defects still exist: poor surface processing quality, low processing efficiency, difficult removal of dust pollution, serious prop abrasion and the like. The introduction of the ultrasonic cutting technology relieves the problems of the honeycomb core material in the traditional processing and high-speed milling. The ultrasonic composite machining technology has a series of better cutting performances, including smaller cutting force, improved machining efficiency, lower energy consumption and wider machining range, and the technology without chip generation can better solve some complex process problems when machining some difficult-to-machine materials, and the machining effect is very obvious. The basic working principle of ultrasonic composite cutting machining is as follows: the ultrasonic generator converts commercial power (220V/50Hz) into an ultrasonic frequency electric signal (generally 20-40 kHz) meeting the requirement; the inverse piezoelectric effect of the piezoelectric transducer converts a high-frequency point signal of the ultrasonic generator into mechanical vibration with the same frequency and outputs the mechanical vibration; the amplitude transformer amplifies the vibration amplitude while transmitting the mechanical vibration of the transducer, and the amplification factor is determined by the shape factor of the amplitude transformer; the ultrasonic vibration system is fixed with the machine tool spindle through the shaft sleeve at the node position, so that the ultrasonic vibration system has reliable connectivity on the premise of not influencing output amplitude; finally, the vibration of the amplitude transformer is transmitted to a cutter, and the multidirectional cutting processing of the honeycomb material is realized by matching with the motion parameters of a machine tool and a main shaft. However, the existing ultrasonic generators have the following disadvantages: firstly, most of the existing ultrasonic generators are heavy, require manual operation on line by personnel, and are not easy to be used in high-automation working occasions; secondly, the working state of the generator cannot be judged in real time by workers, and the occurrence of faults cannot be judged and predicted; and thirdly, in the processing process, the amplitude of the ultrasonic vibration system can be inevitably changed due to stress, temperature rise, abrasion and the like, and the single power output of the current ultrasonic generator is not suitable for the processing field with high precision requirement. And fourthly, the design and research of integrating the ultrasonic generator with the control and acquisition functions are blank at present.

In view of the deficiencies of the prior art, a technique is needed to address this problem.

Disclosure of Invention

Based on the defects in the prior art, the invention provides the multi-gear ultrasonic generation control acquisition electric appliance cabinet.

In order to achieve the purpose, the invention adopts the following technical scheme:

a multi-gear ultrasonic generation control acquisition electric appliance cabinet comprises an upper layer part and a lower layer part, wherein the upper layer part is used for arranging an electric control system, and the lower layer part is used for installing an ultrasonic generator; the electric control system comprises an air switch, a data acquisition control module, a digital quantity output module, an analog quantity input module, a frequency counting module, a relay-contactor control module, a temperature transmitter, a voltage transmitter, a current transmitter, a voltage-stabilized power supply and a terminal block; the air switch is used for being connected with commercial power to provide an alternating current power supply for the electric control system, and the stabilized voltage power supply is used for providing a direct current power supply for the electric control system; the temperature transmitter, the voltage transmitter and the current transmitter are respectively and simultaneously connected with the ultrasonic generator and the analog quantity input module so as to acquire corresponding analog signals of the ultrasonic generator and send the acquired analog signals to the analog quantity input module; the frequency counting module is connected with a built-in transformer of the ultrasonic generator to acquire frequency signals of the ultrasonic generator; the data acquisition control module is connected with the analog quantity input module, the frequency counting module and the digital quantity output module so as to acquire signals acquired by the analog quantity input module and the frequency counting module, process the signals and output digital control signals through the digital quantity output module; the digital quantity output module is connected with the relay-contactor control module and controls the action of the relay-contactor control module through a digital control signal, and the relay-contactor control module is connected with the ultrasonic generator to control the work of the ultrasonic generator; the terminal block is used for arranging relay wiring of an electrical control system.

As an optimal scheme, the multi-gear ultrasonic generation control acquisition electric appliance cabinet is further provided with a remote intelligent terminal, and the data acquisition control module is in data communication interaction with the remote intelligent terminal.

As a preferred scheme, the relay-contactor control module comprises a plurality of relay modules and a plurality of contactor modules, the relay modules are respectively connected with a sound wave inspection switch and the contactor modules in the ultrasonic generator to control on-off, and the contactor modules are respectively connected with a power switch and a transformer coil in the ultrasonic generator to control on-off.

Preferably, the transformer coil is composed of a primary coil and a secondary coil, the primary coil is wound by 42 circles, the secondary coil is wound outside the primary coil, contacts are led out from 12 th, 13 th, 14 th and 15 th circles of the secondary coil and are connected to 4 contactor modules, and the proportion of the primary coil to the secondary coil of the transformer is 42:12, 42:13, 42:14 and 42:15 respectively.

Preferably, the temperature transmitter is connected to a triode on an internal inversion board of the ultrasonic generator.

Preferably, the voltage transducer is connected in parallel to two ends of the output of the ultrasonic generator.

Preferably, the current transducer is connected with the output anode of the ultrasonic generator.

Preferably, the connection between the ultrasonic generator and the electrical control system adopts a quick plug-in electric connector.

Preferably, the air switch is opened in an air mode of 2P10A, the data acquisition control module adopts ADAM-5000L/TCP, the digital quantity output module adopts ADAM-5056SO, the analog quantity input module adopts ADAM-5017, the frequency counting module adopts ADAM-5081, and the relay-contactor module comprises a 6-path relay NO/NC module and 5 alternating current contactors; the upper layer is arranged in two layers, the upper layer is sequentially fixed with a voltage-stabilizing power supply, a data acquisition control module, a digital output module, an analog input module, a frequency counting module, a temperature transmitter, a voltage transmitter, a current transmitter and a relay, and the lower layer is sequentially fixed with 5 alternating current contactors, a terminal row and a 6-path relay NO/NC module.

Compared with the prior art, the invention has the beneficial effects that:

(1) the ultrasonic generator is driven by the data acquisition control module, the real-time acquisition function of temperature, current, voltage and frequency is integrated, the integration level is high, and the problem that the conventional ultrasonic generator is single in function is solved.

(2) According to the invention, the data in the electric appliance cabinet is monitored in real time through the analog input module, so that the identification of the fault state in the cabinet can be identified in time, and fault diagnosis and early warning are realized.

(3) The invention realizes the integration of the internal control of the electric appliance cabinet, can transmit data to a remote intelligent terminal through connection modes such as an Ethernet Modbus and the like, and performs centralized control and monitoring on the electric appliance cabinet at the intelligent terminal.

(4) The invention has high layout concentration, saves space, avoids complex wiring of each module, and has simpler and more tidy interior.

(5) The invention can switch the power of the ultrasonic generator in multiple gears and can be applied to the processing fields with different high-precision requirements.

(6) The power supply and output of the electric appliance cabinet adopt the design of electric connection and quick plug, and the electric appliance cabinet has the characteristics of convenient installation, reliable contact, quick connection and separation, good environmental resistance, high reliability and the like.

Drawings

Fig. 1 is a wiring diagram of a multi-gear ultrasonic generation control acquisition electrical cabinet according to a first embodiment of the invention;

fig. 2 is a schematic layout of an original component of an electrical cabinet for multi-gear ultrasonic generation control and collection according to a first embodiment of the present invention;

wherein: I. an upper layer portion; II, a lower layer part; 1. an air switch; 2. a temperature transmitter; 3. a current transmitter; 4. a voltage transmitter; 5. a frequency counting module; 6. an analog input module; 7. a digital quantity output module; 8. a data connection port; 9. a data acquisition control module; 10. fixing the guide rail; 11. a regulated power supply; 12-16. a contactor; 17. a terminal block; 18-23. a relay; 24. the output of the ultrasonic generator.

Detailed Description

In order to more clearly illustrate the embodiments of the present invention, the following description will explain the embodiments of the present invention with reference to the accompanying drawings. It is obvious that the drawings in the following description are only examples of the invention, and that for a person skilled in the art, other drawings and embodiments can be derived from them without inventive effort.

The first embodiment is as follows:

as shown in fig. 1-2, the multi-gear ultrasonic generation control acquisition electrical cabinet of the present embodiment adopts an easy-to-operate and easy-to-install concept to realize integration of an internal control acquisition system of the electrical cabinet, wherein the electrical cabinet includes an upper layer portion I and a lower layer portion II, the upper layer portion I is used for arranging an electrical control system, and the lower layer portion II is used for installing an ultrasonic generator; the electric control system comprises an air switch 1, a data acquisition control module 9, a digital quantity output module 7, an analog quantity input module 6, a frequency counting module 5, a relay-contactor control module, a temperature transmitter 2, a voltage transmitter 4, a current transmitter 3, a stabilized voltage power supply 11 and a terminal row 17, wherein the air switch 1 is used for being connected with a mains supply to provide an alternating current power supply for the electric control system, and the stabilized voltage power supply 11 is used for providing a direct current power supply for the electric control system; the temperature transmitter 2, the voltage transmitter 4 and the current transmitter 3 are respectively and simultaneously connected with the ultrasonic generator and the analog input module 6so as to acquire corresponding analog signals of the ultrasonic generator and send the acquired analog signals to the analog input module 6; the frequency counting module 5 is connected with two ends of a built-in transformer of the ultrasonic generator to collect frequency signals of the ultrasonic generator; the data acquisition control module 9 is connected with the analog quantity input module 6, the frequency counting module 5 and the digital quantity output module 7 so as to acquire signals acquired by the analog quantity input module 6 and the frequency counting module 5, process the signals and output digital control signals through the digital quantity output module 7; the digital quantity output module 7 is connected with the relay-contactor control module and controls the action of the relay-contactor control module through a digital control signal, and the relay-contactor control module is connected with the ultrasonic generator to control the work of the ultrasonic generator; the terminal block 17 is used for arranging relay wiring of the electrical control system.

Specifically, the upper layer part I is arranged in two layers, the upper layer is sequentially fixed with a voltage-stabilizing power supply 11, a data acquisition control module 9, a digital output module 7, an analog input module 6, a frequency counting module 5, a temperature transmitter 2, a voltage transmitter 4, a current transmitter 3 and a relay through a fixed guide rail 10, and the lower layer is also sequentially fixed with an alternating current contactor, a terminal row 17 and a relay.

Further, the air switch 1 is a 2P10A air switch, the input end of the air switch 1 is connected to AC220V commercial power through a 2-core 1.5-side shielding flexible wire, the live wire and the zero wire of the output end are respectively connected to the terminal row 17 and connected to the relay-contactor module and the stabilized voltage power supply 11, the air switch 1 is arranged at the incoming line end of the electric appliance cabinet, the maximum bearing current is 10A, and the air switch plays a role in protecting the electric appliance cabinet during working.

The data acquisition control module 9 is selected from ADAM-5000L/TCP, and supplies power at DC24V level: the Ethernet adapter with 4 slots, wherein 3 slots are respectively inserted with a digital quantity output module 7, an analog quantity input module 6 and a frequency counting module 5, and after integration, the Ethernet adapter is connected to a remote intelligent terminal upper computer through a Modbus bus interface, namely a data connector 8 by using a super-six twisted pair network cable, is used for signal control and data return inspection between an electric appliance cabinet and the upper computer, adopts an ADAM-5000L/TCP system, supports a Modbus/TCP communication protocol, is easy to integrate, has a communication distance of up to 100m without a repeater, can be remotely configured through the Ethernet, and has low cost, high reliability and high transmission rate; the digital output module 7 is selected from ADAM-5056SO, 16-path source point type isolation with LED display, the COM of the digital output module 7 is connected to the level of DV24V, DO 0-DO 6 are respectively connected to the input end of a 6-path relay module, and strong current is controlled by weak current to control signals; analog input module 6The model is selected to be ADAM-5017, an 8-path analog quantity input module 6, and the temperature transmitter 2, the voltage transmitter 4 and the current transmitter 3 are connected through a single-core 0.3-square AVR; the output end of the temperature transmitter 2 is connected with V of the analog input module 6₀+ and V₀V, the output end of the current transducer 3 is connected with the analog quantity input module 6₁+ and V₁V with voltage transducer 4 output connected to analog input module 6₂+ and V₂Integrating the signals transmitted and output by each transmitter on an upper computer for displaying, thereby realizing real-time parameter acquisition; the frequency counting module 5 is selected from ADAM-5081, 4-channel high-speed counter/frequency module, and C of the frequency counting module 5₀A + and C₀A-connecting two ends of a secondary coil of a high-frequency transformer in an ultrasonic generator so as to realize real-time acquisition of frequency signals; the input end of the voltage transducer 4 is connected to the two ends of the output 24 of the ultrasonic generator in parallel, the collected actual output alternating voltage is converted into a voltage signal of 0-10V, and the voltage signal is output to the analog input module 6; the positive pole of the output 24 of the ultrasonic generator penetrates through the mutual inductance hollow core of the current transducer 3 according to the current direction, the acquired actual current signal is converted into a voltage signal of 0-10V, and the voltage signal is output to the analog input module 6; the temperature transmitter 2 is fixed to a triode on an inversion plate in the ultrasonic generator by a thermocouple through hot melt adhesive, converts the temperature of the collected triode at minus 50-200 ℃ into a voltage signal of 0-10V, and outputs the voltage signal to the analog input module 6; the regulated power supply 11 is powered by AC220V through a terminal block 17, and the output part comprises DC24V which respectively supplies power to the data acquisition control module 9 and the temperature transmitter 2; and a DC15V output part for supplying power to the voltage transducer 4 and the current transducer 3.

The relay-contactor module comprises a set of 6 paths of relay NO/NC modules 18-23 and 5 alternating current contactors 12-16, the input end of the relay module is respectively connected with a digital quantity output module 7, the normally open contact of the relay 23 is connected with the normally open contact A2 of the contactor 16 to realize the function of 'ultrasonic on-off', the normally open and normally closed contacts of the relay 22 are connected with a sound wave inspection switch in an ultrasonic generator to control the on-off of ultrasonic waves, the remaining 5 paths of relays respectively control 5 contactors, the 5 alternating current contactors are respectively connected with a power switch in the ultrasonic generator and 4 secondary coils of a high-frequency transformer to realize the on-off and gear switching of the ultrasonic generator, specifically, the normally open contact of the relay 21 is connected with the normally open contact A2 of the contactor 15 to realize the control of the ultrasonic '4 th gear', and the normally open contact of the relay 20 is connected with the contact A63, the control of ultrasonic wave 3 rd gear is realized, the normally open contact of the relay 19 is connected with the normally open contact A2 of the contactor 13, the control of ultrasonic wave 2 nd gear is realized, the normally open contact of the relay 18 is connected with the normally open contact A2 of the contactor 12, and the control of ultrasonic wave 1 st gear is realized. The normally closed contacts of the relays 23, 21-18 are connected to the neutral line of the AC220V through the terminal block 1717; the normally open contact A1 of the contactor 12-16 is connected to the live wire of the AC220V through a terminal block 1717, and the secondary of the contactor 12 is connected to a main switch in the ultrasonic generator, so that the function of 'ultrasonic start and stop' is realized. The secondary of the contactor 13 is connected to the first contact (12 th turn of the secondary coil) of the secondary coil of the high-frequency transformer in the ultrasonic generator. The secondary of the contactor 14 is connected to the second contact (the 13 th turn of the secondary coil) of the secondary coil of the high-frequency transformer in the ultrasonic generator. The secondary of the contactor 15 is connected to the third contact (the 14 th turn of the secondary coil) of the secondary coil of the high-frequency transformer in the ultrasonic generator. The secondary side of the contactor 16 is connected with a fourth contact (the 15 th turn of the secondary coil) of a secondary coil of a high-frequency transformer in the ultrasonic generator, the 4 secondary coils of the high-frequency transformer in the ultrasonic generator are led out by multi-gear adjustment and are connected with an alternating current contactor, different transformer primary and secondary coil turn ratios (gears) are selected through the digital quantity output module 7, the adopted high-frequency transformer turn ratios are respectively 42:12, 42:13, 42:14 and 42:15, and finally the output power is selected according to different loads, so that the high-frequency transformer has the advantage of wide applicability.

The ultrasonic generator normally inputs 220V mains supply, and after signals are inverted, the magnitude of output voltage can be adjusted through an internally self-made high-frequency transformer, and the turn ratio of the transformer designed and manufactured by the invention is 0-42/0-12-13-14-15. Gear selection can be performed through the steps, and the size of the final output voltage is determined; the power supply interface and the electric signal output interface of the ultrasonic generator are both designed to be connected with an LEMO electric connector for quick plugging, the female head of an LEMO aviation plug is fixed on the back face of the ultrasonic generator through screws, and the female head is welded with two 2-core 1.5-square shielding flexible wires.

The embodiment provides a multi-gear ultrasonic generation control acquisition electric appliance cabinet, adopts the theory of easy operation, easy installation, has realized integrating of the inside control acquisition system of electric appliance cabinet to can realize remote monitoring and control, improve control efficiency, the supporting electric of lathe of being convenient for and control design work develop, improved its stability and reliability, the cost input is reduced.

It should be noted that the above-mentioned only illustrates the preferred embodiments and principles of the present invention, and that those skilled in the art will be able to make modifications to the embodiments based on the idea of the present invention, and that such modifications should be considered as the protection scope of the present invention.

Claims

1. The electric appliance cabinet is characterized by comprising an upper layer part and a lower layer part, wherein the upper layer part is used for arranging an electric control system, and the lower layer part is used for installing an ultrasonic generator; the electric control system comprises an air switch, a data acquisition control module, a digital quantity output module, an analog quantity input module, a frequency counting module, a relay-contactor control module, a temperature transmitter, a voltage transmitter, a current transmitter, a voltage-stabilized power supply and a terminal block; the air switch is used for being connected with commercial power to provide an alternating current power supply for the electric control system, and the stabilized voltage power supply is used for providing a direct current power supply for the electric control system; the temperature transmitter, the voltage transmitter and the current transmitter are respectively and simultaneously connected with the ultrasonic generator and the analog quantity input module so as to acquire corresponding analog signals of the ultrasonic generator and send the acquired analog signals to the analog quantity input module; the frequency counting module is connected with a built-in transformer of the ultrasonic generator to acquire frequency signals of the ultrasonic generator; the data acquisition control module is connected with the analog quantity input module, the frequency counting module and the digital quantity output module so as to acquire signals acquired by the analog quantity input module and the frequency counting module, process the signals and output digital control signals through the digital quantity output module; the digital quantity output module is connected with the relay-contactor control module and controls the action of the relay-contactor control module through a digital control signal, and the relay-contactor control module is connected with the ultrasonic generator to control the work of the ultrasonic generator; the terminal block is used for arranging relay wiring of an electrical control system.

2. The multi-gear ultrasonic generation control collection electric cabinet as claimed in claim 1, wherein the multi-gear ultrasonic generation control collection electric cabinet is further provided with a remote intelligent terminal, and the data acquisition control module is in data communication interaction with the remote intelligent terminal.

3. The electrical cabinet for generating, controlling and collecting multi-gear ultrasonic waves as claimed in claim 1, wherein the relay-contactor control module comprises a plurality of relay modules and a plurality of contactor modules, the plurality of relay modules are respectively connected with the sound wave inspection switch and the plurality of contactor modules in the ultrasonic generator to control on-off, and the plurality of contactor modules are respectively connected with the power switch and the transformer coil in the ultrasonic generator to control on-off.

4. The electrical cabinet for multi-gear ultrasonic generation control collection according to claim 3, wherein the transformer coil is composed of a primary coil and a secondary coil, the primary coil is wound by 42 turns, the secondary coil is wound outside the primary coil, contacts are led out from 12 th turn, 13 th turn, 14 th turn and 15 th turn of the secondary coil and are connected to 4 contactor modules, and the proportion of the primary coil to the secondary coil of the transformer is 42:12, 42:13, 42:14 and 42: 15.

5. The electrical cabinet for generating, controlling and collecting multi-gear ultrasonic waves as claimed in claim 1, wherein the temperature transmitter is connected to a triode on an internal inverter board of the ultrasonic generator.

6. The electrical cabinet for generating, controlling and collecting multi-gear ultrasonic waves as claimed in claim 1, wherein the voltage transmitter is connected in parallel to two output ends of the ultrasonic generator.

7. The electrical cabinet for generating, controlling and collecting multi-gear ultrasonic waves as claimed in claim 1, wherein the current transducer is connected with the output anode of the ultrasonic generator.

8. The electrical cabinet for generating, controlling and collecting multi-gear ultrasonic waves as claimed in claim 1, wherein the connection between the ultrasonic generator and the electrical control system is by means of a quick-plugging electrical connector.

9. The electrical cabinet for multi-gear ultrasonic generation control collection according to claim 1, wherein the air switch is opened by 2P10A, the data collection control module adopts ADAM-5000L/TCP, the digital output module adopts ADAM-5056SO, the analog input module adopts ADAM-5017, the frequency counting module adopts ADAM-5081, and the relay-contactor module comprises 6 paths of relay NO/NC modules and 5 alternating current contactors; the upper layer is arranged in two layers, the upper layer is sequentially fixed with a voltage-stabilizing power supply, a data acquisition control module, a digital output module, an analog input module, a frequency counting module, a temperature transmitter, a voltage transmitter, a current transmitter and a relay, and the lower layer is sequentially fixed with 5 alternating current contactors, a terminal row and a 6-path relay NO/NC module.