EP0761853A1 - Apparatus for controlling a running yarn - Google Patents

Abstract

A monitor for moving yarn (1) has a sensing head with a spatially separate evaluation unit (7) connected to it. The sensing head has a first part (2) with a connection (5) to a first part (6) of the evaluation unit (7) and a further part (9) with a removable connection (8, 10) to the first part (2). The evaluation unit has a further part (16) with a removable connection (17) to evaluate the signal from the further part (9) of the sensing head.

Description

The invention relates to a device for monitoring a yarn moving in its longitudinal direction, with a measuring head and an evaluation unit that is spatially separated from and connected to the measuring head.

Known devices for monitoring a moving yarn work on the capacitive or the optical measuring principle. Depending on the measuring principle, such devices each have their preferred field of application and are specifically designed for this.

From US-A-5,054,317 a device for monitoring and / or measuring parameters of a running, wire or thread-like test material is known, in which a capacitive as well as an optical measuring element is arranged in a measuring gap. The two measuring elements form two measuring zones that can overlap each other.

A disadvantage of these known devices can be seen in the fact that, depending on whether one or the other or even both measuring principles are to be used for monitoring the yarn, a device specifically designed for this purpose must be provided. For the manufacturer, this means that he has to develop and provide several versions, which also means increased logistical expenses.

In the above-mentioned known device with optical and capacitive monitoring of the yarn, the arrangement in the same measuring gap necessitates a mutual adaptation of the two measuring systems, which leads to compromises, and which therefore does not bring the individual measuring systems to their best advantage.

The problem to be solved by the invention, as characterized in the claims, is now one To create a device with which measuring elements that work, for example, according to different physical principles or that measure different parameters, can be used optimally without increasing the design and logistical effort and also guaranteeing great flexibility in use in operation.

The object is achieved in that the measuring head has a first part, for example working according to a first measuring principle, which is connected via a connection to a first part of an evaluation unit for evaluating the signals from the first part, for example according to the first measuring principle. A second part of the measuring head, for example working according to a second measuring principle, can be connected to the first part of the measuring head via a detachable connection. Finally, the evaluation unit also has a second, second part connected via a detachable connection for evaluating signals from the second part, for example according to a second measuring principle. Optionally, the measuring head and evaluation unit can also include third and further parts.

This results in a modular structure, for example of an optical and a capacitive measuring head, one measuring head serving as the base head and the other measuring head being attachable, for example, to the base head. This results in a continuous measuring gap for the base head and the further measuring head. The evaluation units that are not part of the measuring head and that cannot be located in the immediate vicinity of the measuring head due to space constraints result in a comparable design with a basic evaluation unit for the basic head and an additional plug-on evaluation unit for the further measuring head. A common connecting line is then provided for both measuring heads and evaluation units.

The advantages achieved by the invention can be seen in particular in the fact that the production of such devices can be further standardized, because there are only a few matching measuring heads and evaluation units, some of which have the same dimensions. For users who want to install such devices in their yarn spinning machines, for example, there is increased flexibility because they do not have to immediately decide whether they want to install an optical or a capacitive measuring system, for example. He can first install a first measuring system and later buy the second or further measuring systems and retrofit the spinning machine. He can also install two or three measuring systems together and, depending on the thread, activate one or the other measuring system, or assign a separate task to each measuring system. If necessary, one of the two measuring systems can be removed, deactivated or otherwise removed. You can switch between the two measuring systems at any time, even during operation. For example, one measuring system can monitor the uniformity of the yarn and the other measuring system the foreign fibers or foreign substances in the yarn. Another advantage is that physical quantities that are measured in either part of the measuring head or occur in any other way do not influence each other. Each part can be specifically and specifically designed to record a certain textile size. Then it is also possible to derive further textile-related variables when evaluating the signals from the parts of the measuring head. A certain "three-dimensional" measurement of the yarn can be achieved with the aid of such derived sizes, parameters such as the volume, the density, the structure of the yarn etc. being able to be determined.

• Figur 1 eine vereinfachte perspektivische Darstellung der erfindungsgemässen Vorrichtung und
• Figur 2 eine schematische Darstellung einer weiteren Ausführung der Vorrichtung.

The invention is explained in more detail below using an example and with reference to the accompanying figures. It shows:

• Figure 1 is a simplified perspective view of the inventive device and
• Figure 2 is a schematic representation of a further embodiment of the device.

In FIG. 1, for a yarn 1, a first part 2 of a measuring head can be seen, on which the yarn 1 is moved past in a measuring gap 3 in a manner known per se. The first part 2 has a connection 4 with a plug connection for a connection 5 to a first part 6 of an evaluation unit 7. The evaluation unit 7 is shown here only schematically by its carrier plates, on which electronic components are arranged, which form an evaluation circuit, in a manner known per se but not shown here.

The first part 2 of the measuring head also has a connection 8 for a plug connection to a second part 9 of the measuring head. In the second part 9, a counterpart 10 for connection 8 is provided. In the operational state, the second part 9, lying on a side surface 11 of the first part 2, is mechanically detachably connected to the latter, for example via screw connections 12, 12, 13, 13 ', 14, 14' and 15, 15 '. The electrical connection of the two parts 2 and 9 of the measuring head takes place via the plug connection 8, 10. The outer shape of the measuring head with its two parts 2 and 9 is preferably chosen and dimensioned such that an attachment to the spinning and winding machines known today such as so far a single sensor can be made. In the same way, a further part 19 can also be attached to the first or second part.

A comparable structure is provided in the evaluation unit 7, in which the first part 6 and a second part 16 are also electrically connected via a plug connection 17 and mechanically via plug or screw connections not shown here. The two parts 6 and 16 can also be accommodated in a common housing 18, of which a part is indicated schematically here. Here, too, the structure can be expanded to include other parts.

With such a device, the most varied of parameters such as the mass of the yarn, uniformity of the yarn, foreign matter content or foreign fiber content of the yarn, etc., per se be determined in a known manner. In addition, it is also possible to use the first part 2 of the measuring head to determine a first parameter, for example the mass of the yarn, and the second part 9 to determine the foreign fiber content of the yarn. In this case, the first and second parts 6, 16 of the evaluation unit 7 are also designed to determine these parameters. The evaluation unit 7 is designed in a manner known per se for evaluating electrical signals which are emitted by one or more parts 2, 9 which operate optically, capacitively or on a further principle. It converts these signals into measured values.

FIG. 2 shows an embodiment of the device at the work stations 20, 21, 22, 23, 24 of a spinning or winding machine, a first part 25, 26, 27, 28, 29 of a measuring head via a line 30, 31, 32, 33, 34 are connected to a single, common first part 35 of an evaluation unit. This also has a common second part 36 for second parts 37, 38, 39, 40, 41 of the measuring heads. As already described for FIG. 1, the second parts 36-41 are detachably connected to the first parts 25-29 and 35.

With this construction according to the invention, a measuring head system can be constructed which provides base parts 2, 6 for frequently requested measurements and additional parts 9, 16 for more specific or less frequent measurements. The base parts 2, 6 and the additional parts 9, 16 form apart from the connection to one another and possibly their supply in mechanical and electronic terms autonomous units. In a system with several spinning or winding machines, which are equipped with basic parts of the measuring heads and evaluation units, a single work station or a machine with additional parts can also be temporarily equipped to handle a special task. By exchanging the additional parts between individual work stations or machines, it is also easier to find out whether an error has occurred on the measuring system or on the machine. So the machines can be equipped with such measuring head systems gradually, which allows the textile industrialist, with less Participation in ongoing technical progress in the field of measuring and monitoring yarn.

Claims (7)

Device for monitoring a yarn (1) moving in its longitudinal direction, with a measuring head and an evaluation unit (7) spatially separated from and connected to the measuring head, characterized in that the measuring head has a first part (2) with a connection ( 5) to a first part (6) of the evaluation unit (7) for evaluating a signal from the first part of the measuring head, that the measuring head has a further part (9), with a detachable connection (8, 10) to the first part and that the evaluation unit has a further part (16) connected via a detachable connection (17) for evaluating the signal from the further part (16) of the measuring head. Device according to claim 1, characterized in that the first part (2, 6) is designed to work according to a first measuring principle and the further part (9, 16) is designed to work according to a further measuring principle. Apparatus according to claim 2, characterized in that the first measuring principle works capacitively. Device according to claim 2, characterized in that the further measuring principle works optically. Device according to claim 1, characterized in that the first part is used to monitor a first parameter and the further part is used to monitor a further parameter. Device according to claim 1, characterized in that the releasable connections are plug connections. Apparatus according to claim 1, characterized in that the evaluation unit has a common first part (35) for several first parts (25-29) of measuring heads and a common further part (36) for several further parts (37-41) of the measuring heads.

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