EP0900470A1

EP0900470A1 - Electrical control system for a sewing-machine drive

Info

Publication number: EP0900470A1
Application number: EP97915397A
Authority: EP
Inventors: Sevki Hosagasi; Michael Kilian; Thomas Maibaum
Original assignee: Quick-Rotan Elektromotoren GmbH
Current assignee: Quick-Rotan Elektromotoren GmbH
Priority date: 1996-05-22
Filing date: 1997-03-18
Publication date: 1999-03-10
Also published as: WO1997044885A1; DE19620533A1; TW398114B

Abstract

The invention concerns an electrical control system for a sewing-machine drive, with a mains connection for alternating voltage, a rectifier circuit to which an intermediate circuit voltage is applied, and a main drive which is supplied by the latter. The system further comprises adjusting elements connected to the control system. The electrical control system is characterized in that the adjusting elements are connected to the microprocessor by means of control elements to which the intermediate circuit voltage is applied.

Description

ELECTRIC CONTROL FOR A SEWING DRIVE

The invention relates to an electrical control for a sewing drive according to the preamble of the main claim.

Since sewing machines are relatively simple machines, part of the electronic control controls the operating elements such as thread trimmer, presser foot, etc., while the other part controls the main drive in the form of a motor. This is used in the sewing industry as an asynchronous motor with an electromechanical clutch / brake system, DC motors and servo motors. These drives can run at predetermined speeds and position them at predefinable angles.

In the asynchronous machine, the clutch / brake system is preferably supplied with a low voltage of less than 50 V, mostly 24 V DC. Clutch coils or brake coils are driven in a clocked manner from this voltage source. This sets the desired speed of the drive.

The servomotors (DC motor or brushless DC motor) are supplied in this Performance class directly from the network. The mains voltage is rectified and buffered with a sufficiently large capacity. The voltage across the capacitor forms the so-called intermediate circuit voltage, which then operates the motor via the electronic assemblies and components. Since the motor is operated directly at the mains potential, the regulations and guidelines for mains operation are used for this part of the control.

In sewing technology, the control elements are usually only controlled with a low voltage of <50 V. The reason is that not all control units and other equipment can be designed for network potential and the protection of the operator from an electric shock must be guaranteed. However, since the control contains a part with mains potential for controlling the main drive, the parts with extra-low voltage potential must be safely separated from the mains potential in the control itself (safety isolation). This means that in addition to compliance with minimum distances between the lines of the voltage circuits, a potential separation for certain input and output signals must either take place via optocouplers or transformers between the two voltage circuits.

The use of several voltage circuits means that several voltage sources are also required for this. For example, a 24 V voltage source for a short-term (several hundred ms) current of 10 A is used to supply the control elements. The electronic circuits require a power supply unit with 5 V and approx. 1 A and the electronic components for controlling the main drive on the mains voltage side require one Another power supply unit with a voltage between 5 and 15 V and a current of 1 A. In sewing technology, the control elements are generally voltage-controlled. In order to ensure that these elements function properly, the voltage must be relatively constant. Therefore, the intermediate voltage cannot be used directly to supply the control elements. The DC link voltage depends on the one hand on the level of the mains voltage and on the other hand on the operating state of the motor. In Breinsbetrieb the motor acts as a generator and feeds electrical energy back into the intermediate circuit, so that its voltage increases. Feeding the braking energy back into the network is ruled out in sewing technology for reasons of economy. Instead, when a predetermined voltage is reached, a resistor is switched on, which converts the further braking energy into heat.

The invention is based, an electronic control according to the preamble of the task

Main claim so that only one

Voltage source for controlling both the main drive and the control elements is necessary.

This object is achieved in a generic control according to the preamble of the main claim according to the invention by its characterizing features. Appropriate refinements and developments are characterized in the subclaims.

According to the invention, all voltages can be related to a reference potential and the signal transmitters mentioned above are also eliminated. You can advantageously feed all modules from the same voltage source, namely the intermediate circuit voltage, which also the electronic components, including the Microprocessor supplied. The control elements such as magnets, valves etc. can therefore also be supplied with PWM technology via the DC link voltage. This leads to a saving of the relatively expensive voltage source with 24 V DC voltage and for a short time 10 A. These control elements are designed for the intermediate circuit voltage, so that the current is reduced in inverse proportion to the voltage increase compared to the 24 V supply. If one also takes into account the operating conditions occurring in this circuit, the voltage fluctuates in a ratio of 1: 2. In order to stabilize the voltage for the control elements, the DC link voltage is measured at short intervals, namely a few ms by an A / D converter. The microprocessor can then determine a pulse-pause duty cycle at a predetermined frequency in such a way that the control elements see a voltage that is constant on average, even though they are controlled from the intermediate circuit. The maximum voltage for the control elements that can be obtained from the DC link corresponds to the minimum value of the DC link voltage that occurs at the lowest input voltage and maximum motor load. The control elements should preferably be designed for this voltage, so that the control elements can be used with smaller currents.

An embodiment of the invention is explained below with reference to the drawing. In this shows:

Figure 1 is a block diagram of the invention

Control; and

FIG. 2 shows a detail of the control according to FIG. 1. 5 with the network connection is designated in the form of an AC voltage. This is connected to a rectifier circuit, denoted overall by 6, to the output of which a capacitor, denoted overall by 7, is connected. The so-called intermediate circuit voltage is present at this. A voltage of + 5V for the microprocessor 9 and a monitoring and control circuit 10 for the bridge 11 of the main drive, which is denoted overall by 12, in the form of a motor, is applied via a power supply unit designated by 8. The output of the microprocessor 9 is connected to the control elements (not shown) 14 via control elements 13. The controls are connected to the DC link voltage.

The microprocessor 9 together with the wiring is shown in more detail in FIG. 2.

Via an ohm 'see voltage divider R] _ and R2 connected to the total designated 15 input of the microprocessor 9. The input is formed by an analog-digital converter 16. The output 17 of the microprocessor is connected to the control elements 13. These form an electronic on and off switch which controls the intermediate circuit voltage at a predetermined frequency in a predefined pulse duty factor (pulse width modulation). This pulse width, which can be controlled by the microprocessor, is set as a function of the measured value of the intermediate circuit voltage in such a way that the adjusting elements see the correspondingly lower voltage (resulting from the pulse-pause ratio).

Claims

EXPECTATIONS

1.Electric control for a sewing drive with a mains connection (5) for an AC voltage, with a rectifier circuit (6), to which an intermediate circuit voltage is applied, and with a main drive (12) supplied by the latter as well as control elements (14) connected to the control,

characterized,

that the control elements are connected via control elements (13) to the microprocessor (9) to the intermediate circuit voltage.

2. Control according to claim 1, characterized in that the intermediate circuit voltage, optionally via an ohm 'see voltage divider (Ry R2) is applied to the microprocessor (9).

3. Control according to claim 1 or 2, characterized in that the input (15) of the microprocessor (9) is designed as an input of an A / D converter (16).

4. Control according to one of claims 1 to 3, characterized in that the output (17) of the Microprocessor (9) switches the intermediate circuit voltage on and off in a controlled duty cycle.

5. Control according to claim 4, characterized in that the output (17) of the microprocessor (9) is pulse width modulated.

6. Control according to one of claims 1 to 5, characterized in that the control elements (13) are located at the output (17) of the microprocessor (9).

7. Control according to claim 6, characterized in that the control elements are designed as an electronic on-off switch.