JPH03161531A - Method and device for inspecting function of sensor in operating device - Google Patents

Abstract

PURPOSE: To systematically inspect the functions of the sensors of a working device by disconnecting the sensors from the working control section of the working device, coupling the sensors to an inspection circuit and guiding simulators along the sensors. CONSTITUTION: The simulators 6 and 6' are disposed within the inspection region of a spinning frame, etc., and the working device 2 is shifted to the test position on the outer side of a working region a for the purpose of inspection. When a signal generator 12 acts on the sensor 13 of the working device 2, the simulators 6 and 6' exist in the positions relative to the sensors 4 and 4' and the working controller 7 is changed over to a testing device 8 by the switch 9 in the position. The testing device 8 stops the working device 2 and successively activates all of the simulators 6 and activating members 30 and 40. Whether the sensors 4, 4' and 4" receiving the action emits the prescribed signals or not is inspected. When the signals are not generated, signal devices 10 and 11 are activated to announce a malfunction.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a method and a device for checking the functionality of sensors controlling individual working elements in a working device moving along a textile machine, in particular a spinning frame.

Working devices in a spinning machine, such as an automatic splicing device or an automatic bobbin changing device, are equipped with a large number of sensors that control and monitor the operation of these devices. Active, optical sensors sense the presence and absence of threads, rovings, tubes, bobbins, etc.

Sensors that control the movement device, movement speed, work preparation state, etc. of the work device respond to a switch mechanism provided along the movement path of the work device. A sensor inside the work device that monitors whether the work mechanism has reached its end position generates a malfunction signal if the work mechanism does not reach its end position. Such sensors may stop working or become ineffective, which may cause the work equipment to become inoperable or
Incorrect operations may occur, resulting in dead time and damage. Checking the functionality of sensors is difficult and problematic in that the sensors respond in different ways and it is extremely difficult to simulate the actions initiated by the responses. Therefore, a systematic check of the functionality of the sensor is generally not carried out, so that sensor malfunction generally becomes apparent only after the implement malfunctions or is damaged.

The object of the present invention is therefore to provide a method and a device that make it possible to systematically check the functionality of the sensors of a working device.

This task is accomplished according to the invention by the following work steps: - decoupling the sensor from the work control of the working device and connecting it to the inspection circuit; - guiding the simulator along the sensor; and/or - guiding the simulator along the sensor; guided along the sensor and/or - operating a simulator in front of the sensor. In this case, it is possible to use the simulators simultaneously or sequentially.

In a first embodiment of the invention, the shearer is provided in an inspection position located outside the normal working area of the working device along the spinning machine on which the working device operates. There is.

In a second embodiment of the invention, the short rake is built into the working device.

In the first embodiment, a corresponding connection between the test device in the working device and the simulator in the spinning frame is formed in the inspection position.

The simulator is tuned to Senna's operating behavior. That is, the object to be recognized must be located in front of the active optical sensing device.

The magnetic field must simulate a sensor acting on magnetic forces. The switch mechanism must pass by a sensor that reacts as it passes by the switch m.

A sensor that monitors the arrival of the end position of a work element can monitor when this end position is achieved. In these cases, the test control can also be combined with the usual control of the working device, as long as the test control induces a corresponding movement of the actuating member.

In the apparatus for carrying out the method according to the invention, a test device is provided in the work device, and this test device includes a signal generator, a changeover switch between the work control device of the work device and this test device, and and/or an actuating member for moving the signal generator. The present invention will be described in detail below with reference to embodiments illustrated in the accompanying drawings. 1 and 3 each show a plan view of a ring spinning machine 1, in which a working device 2 functions, for example, as an automatic splicing device or an automatic bobbin changing device in working areas a and a'. Reference numeral b indicates the transition path between work area a and work area a'. A signal generator 15 is provided in the working area a and the working area a', which signals the sensors 4 and 4' arranged oppositely in the working device when the working device passes by.
These sensors 4, 4' are activated via the control device 7 in the working device and, in particular, control and monitor the working behavior of the working device. A further sensor 4'' is arranged in the working device 2 and is subjected to the action of a signal generator 15' which is actuated via the control unit 3l by means of an actuating member 40. The embodiment of the invention illustrated in FIG. In this case, simulators 6 and 6' are provided in area b for checking the sensors at the start or end of the ring spinning frame l.
To carry out this inspection, the working device 2 is located in a test position 3 outside the working areas a and a'. This sensor 4 can be
For example, sensors that are inspected by connecting and disconnecting magnetic force or light. The sensor 4', on the other hand, is a sensor, e.g. a mechanical scanning element, by which the ciemirator 6 has to pass for inspection, and is actuated by the piston-cylinder unit 30 and controlled by the control unit }3.
Controlled by 1. The sensor 4'' is a terminal switch which is scanned when the working mechanism and the signal generator 15' attached thereto are moved to their end position and the response of the sensor 4'' is checked. In order to check the sensors 4, 4', 4', the scanning device 2 is equipped with a test device 8, which controls the switching between the signal device IO, 1l, the control device 7 of the device device 2 and the test device 8. It is connected to the switch 9 and via conductors to the simulator 6 in the ring spinning frame l and to actuating elements 30 and 40 for actuating the signal generator 15' or the simulator 6' in the working device 2 or in the ring spinning frame l. It has been done. Simulator 6 installed inside the ring spinning machine
and 6' and to the actuating member 30 are made via a connecting member 5 in the conductor 16, for example a loop connection. When the signal generator 12 provided in the ring spinning machine 1 acts on the sensor 13 provided in the work/device 2, the work device 2 reaches the point M3, and at this position the work device 2 is activated. A simulator 6 is placed opposite the sensors 4 and 4'.
, 6' are located, and the test device 8 is operated in this position.

The test device stops the working device 2 and switches the changeover switch 9 to the position shown so that the sensors 4, 4', 4
'' output signal is not given to the work device 7 but to the test device 8.The test device then sequentially activates all the simulators 6, 6' and the actuating members 30, 40, thereby 4, 4', 4'' are acted upon by signal generators l5 and 15' during operation. At the same time, the test device 8 checks in each case whether the sensor being acted on emits a predetermined signal. If no signal is emitted, this test device
, 11, thereby informing the worker of the malfunction.

In the embodiment according to FIGS. 3 and 4, the simulators 6, 6' are all located in the working device 2, and the inspection is carried out in the region b either on the move or stationary.

In this case too, a test device 8 is connected to the signal generator 10, 1l in the working device 2, a changeover switch 9 between the control device 7 of the working device 2 and the test device 8, and a switch element cooperating with the test connection 12. 13 are provided. Working device 2
The sensors 4, 4'41 are equipped with corresponding ξ shutters 6, 6.
A simulator 6' and a signal generator 15' pass by the sensors 4', 4' via the piston-cylinder units 30, 40 and the control unit 31. The inspection process in this embodiment is the same as in the embodiments shown in FIGS. 1 and 2. The sensor of the device according to the invention can be mechanically (cam/switch) or magnetically (magnet/reed switch; magnet/coil)
, optically (objective lens/optical scanning element, optical device/light barrier), acoustically, piezoelectrically or triboelectrically. The load corresponding to the actuation can be applied by passing the working device 2 next to the corresponding sensor, by passing a working element in the working device 2 next to the sensor, or by passing the load next to the sensor, for example by cams, magnets or other objects. This is done by placing an actuation factor like this in front of the sensor. The activation load for inspection is carried out by a simulator passing by the sensor, by a working mechanism passing by the sensor while inspecting it, or by the simulator being actuated in front of the sensor.

When the simulators 6, 6' are installed on the ring spinning frame 1, the working device 2 is fundamentally located at the tip of the ring spinning frame so that the simulators in front of the sensors 4, 4' are activated for inspection. Must be present at inspection position 3.

However, in this case, the sensors 4', 4' of the simulator 6'
It is also possible to have the passage by the area b take place during operation of the working device 2. It is also possible for the working mechanism in the working device 2 to pass through within the area b while the working device 2 is in operation.

If the simulators 6, 6' are all installed in the working device 2, the working device 2 does not need to stop for inspection, but must be in the inspection position. The pre-inspection is then carried out in area b during the work. Overall, an automatic check of the functionality of the individual sensors controlling the working elements of the working device 2 moving along a textile machine, in particular a spinning frame, is carried out, so that in the unlikely event of a malfunction in the functioning of the sensors, this can be checked. This is advantageous because it can be recognized at an appropriate time, and death time and disability can be avoided.

[Brief explanation of the drawing]

FIG. 1 is a schematic plan view of a ring spinning frame in a checking position with a working device; FIG. 2 is a block diagram of the device according to FIG. 1 for checking the function of the individual sensors controlling the working elements; FIG. 4 is a schematic plan view of another embodiment according to the invention for checking during movement of the working device in area b; FIG. 4 is according to FIG. 3 for checking the function of the individual sensors controlling the working elements; Block diagram of the device. The symbols in the figure are: l...Ring spinning machine, 2...Work device, 3...Inspection position, 4, 4', 4''...Sensor, 6, 6'
...Simulator, 7...Work control device, 8...Testing device, 9...Selector switch, 10, 0...
Signal device, 13...sensor, l5, 15'...
Signal generator, 30, 40... Operating member, a, a'
... Working area, b... Transition area at the inspection position.

Claims (1)

[Claims] 1. A method for checking the functionality of a sensor controlling individual working elements in a working device moving along a textile machine, in particular a spinning frame, comprising the following working steps: decoupling the work control of the device and connecting it to the inspection circuit; - guiding the simulator along the sensor; and/or - guiding the working element along the sensor; and/or - connecting the simulator in front of the sensor. A method for checking the functionality of a sensor controlling a working element of a working device, comprising: activating a working element of a working device. 2. The method according to claim 1, wherein the simulator and the signal generator are activated simultaneously. 3. The method according to claim 1, wherein the activation of the simulator and the activation of the signal generator are performed in sequence. 4. End position - the monitoring sensor is checked when this end position has been achieved and the working element has ceased its own movement.
The method described in any one of 3 to 3. 5. In a device for checking the function of sensors controlling individual working elements in a working device moving along a textile machine, especially a spinning frame, a test device (2) is installed in the working device (2).
8) is provided, and this test equipment is connected to a signal generator (1).
0, 11), a changeover switch (9) between the work control device (7) of the work device (2) and this test device (8), and /
or the actuating member (3) that actuates the signal generator (15').
0, 40) and the sensor (4', 4'') opposite the simulator (6, 6') and the signal generator (15')
A device for checking the function of a sensor that controls a working element of a working device, characterized in that it is equipped with: 6. The inspection position (3) is the working device (
2) is present in the working area (a, a') of claim 5.
The device described. 7. A simulator (6, 6') is provided beside the spinning machine (1), and at least one connecting member (5)
6. Device according to claim 5, characterized in that a is provided between the working device (2) and the spinning frame (1). 8. Device according to claim 5, characterized in that the simulator is provided in the working device (2). 9. A test circuit (12,
13). The device according to claim 7 or 8, wherein: 13) is provided.