CS262244B1 - Circuit Tester Element Diagnostic Module - Google Patents

Abstract

The diagnostic module of the circuit element tester is a device for testing circuit elements in the production of electronic devices in the field of automation of measurement technology. The first output of the program control block is connected to the switch control block, the outputs of which are also the inputs of the switch block, while the second output of the program control block is connected to the tester, the outputs of which are also the inputs of the precision impedance block, the output of which is also the input of the switch block, which is provided with logic level inputs.

Description

The diagnostic module of the circuit element tester is a device for testing circuit elements in the production of electronic devices in the field of automation of measurement technology. The first output of the program control block is connected to the switch control block, the outputs of which are also the inputs of the switch block, while the second output of the program control block is connected to the tester, the outputs of which are also the inputs of the precision impedance block, the output of which is also the input of the switch block, which is provided with logic level inputs.

262243

262243

The invention relates to a diagnostic module of a circuit element tester, which solves the self-diagnosis of a test device for testing circuit elements in the production of electronic devices.

The previously known test equipment must be periodically tested in operation, verifying their functionality and accuracy. Self-diagnosis of these test equipment is solved by connecting the equipment to universal measuring instruments and tools; e.g. subnormals, decades, meters of individual electrical parameters, by manually performing the prescribed measurements. This method is lengthy and largely dependent on the level of the operator or the installation of special diagnostic modules, which, upon the operator's request, perform the diagnostics automatically. The diagnostic module of each tester must be designed specifically for the given type of tester.

The diagnostic module of the circuit element tester according to the invention is adapted for self-diagnosis of the circuit element tester capable of measuring the interconnection network, the resistance network and individual digital integrated circuits on the measured units and its essence lies in the fact that the first output of the program control block is connected to the switch control block, the outputs of which are also the inputs of the switch block, while the second output of the program control block is connected to the tester, the outputs of which are also the inputs of the precision impedance block, the output of which is also the input of the switch block, which is provided with logic level inputs.

Using the diagnostic module of the circuit element tester significantly speeds up self-diagnosis compared to manual diagnostics. The tester user can check the functionality of the device at any time before starting the actual testing. At the same time, the diagnostics are significantly more precise, so the user, without the help of a specialized service, is able to diagnose any possible defect in the tester circuits himself, with an accuracy of at least a replaceable module, for example a printed circuit board. This in turn leads to better usability of the tester. Another advantage is low acquisition costs and easy operation.

A block diagram of a specific embodiment of a diagnostic module of a circuit element tester according to the invention is shown in the attached drawing.

The block 12 of precise impedances is formed by resistors, the block 13 of switches is formed by electromechanical elements, the block 14 of switch control consists of logic elements and the block 15 of program control forms the microprocessor controller of the tester.

The first output 151 of the program control block 15 of the diagnostic module of the circuit tester is connected to the switch control block 14, whose outputs 141, 142 are also the inputs of the switch block 13, while the second output 152 of the program control block 15 is connected to the tester 1, whose outputs 121, 122 to 12N are also the inputs of the precision impedance block 12, whose output 133 is also the input of the switch block 13, which is provided with logic level inputs 131, 132.

The function of the diagnostic module of the circuit tester can be characterized as follows.

' The program control block 15 can control both the functions of the tester and, through the switch control block 14, the switch block 13. It can thus model the boundary conditions for the tester 1 that it could encounter during real testing, e.g. logical states 0, 1 connected to the tester's measuring terminals via a defined resistance and the "disconnected" state. In these states, the program control block ¹⁵ tests the tester's ability to supply nominal levels of logical states at nominal load. Furthermore, it is possible to test the tester's ability to measure the interconnection or resistance network with the switches disconnected using the program control block 15. From the manifestations of possible faults, the program control block 15 evaluates the probable cause of the fault and displays it for the operator on the communication means of the tester 1.

The diagnostic module of the circuit element tester can be advantageously used in the field of automation of measurement technology in the production of electronic devices.

subject

Diagnostic module of a circuit element tester, characterized in that the first output (151) of the program control block (15) is connected to the switch control block (14J), the outputs (141, 142) of which are also the inputs of the switch block (13), while the second output (152) of the block

OF THE INVENTION (15) of program control is connected to a tester (lj, whose outputs (121, 122 to 12N) are also the inputs of a block (12J of precise impedances, whose output (133) is also the input of a block (13) of switches, which is provided with inputs (131, 132) of logic level.

drawing sheet

262243

Severography, π. p. závod 7, Most

Price 2.40 KCs

CZECHOSLOVAK SOCIALIST REPUBLIC llAt DESCRIPTION OF THE INVENTION TO THE AUTHOR CERTIFICATE 262244 (11) (Bl) (51) Int. Cl. ⁴ B 85 H 54/42 8 (22) Registered 06 07 87 (21) (PV 5093-87.P) OAAD FOR VINE CLIMBERS (40) Published 1S 07 88 (45) Issued 15 05 89 AND DISCOVERIES

(75)

Author of the invention: HLAVÁČEK IVO ing., KRATOCHVÍL JIŘÍ, BRNO [54) Device for winding conical or varioconic coils

The solution relates to a device for winding conical or varioconic bobbins and is intended especially for textile machines with a constant feed speed of the supplied yarn. The essence of the solution lies in the fact that the 2e driving support roller is provided with a transition ring in both areas of change of the angular deflection of the rotating transfer ring element, the diameter of which increases or decreases continuously with respect to the diameter of the central part of the driving support roller.

Fig. 4

The invention relates to a device for winding conical or varioconic bobbins, in particular on textile machines with a constant yarn winding feed speed.

When winding conical or varioconic bobbins on textile machines with a constant feed speed of the yarn being wound, the known systems ensuring this winding must respond to the changing diameter of the winding bobbin, which increases proportionally with each additional layer of yarn being wound and also changes in relation to the immediate location of the yarn being wound onto the bobbin. In order to maintain a constant tension of the yarn when it is wound onto the bobbin, various types of compensators are used on these machines, such as mechanical with swinging pulleys, spring, air, lever and others, which compensate for the differences between the winding and feed speeds of the yarn.

Compensators are usually combined with a design modification of the smooth drive roller, which consists in creating a narrow zone of increased friction on this roller for frictional contact with the wound coil, formed, for example, by grooving, surface adhesion treatment, and the like.

The winding of the coil realized by the mentioned means is not completely perfect, the design of these means is complex and their operation demanding in maintenance and adjustment. Moreover, they are only suitable for a narrow range of conical coils. An unpleasant accompanying phenomenon is the inhomogeneity of the winding in the places of contact of the wound coil with the smooth part of the drive cylinder compared to the place of its contact with the zone of increased friction.

Other known winding devices are focused on such an arrangement of the bobbin drive that ensures its drive precisely at the point where the yarn being wound runs onto it, which significantly improves the conditions for winding the yarn onto the bobbin and therefore eliminates the need to use the above-mentioned compensators. The bobbin is wound with a constant supply of yarn, while the speed of the winding bobbin is periodically changed.

One of the known devices of this type comprises, first of all, a transmission ring element in the form of a belt or strap, which is loosely wrapped around a smooth drive roller and directly drives the winding bobbin during its simultaneous reciprocating movement along it, together with the moving yarn distributor. In the area of its movement between two extreme dead ends, it runs smoothly and practically spontaneously. At the extreme dead end, however, it is forced to abruptly change the direction of its rotation and movement towards the longitudinal axis of the driving roller. This rapid change causes the belt, whose modulus of elasticity is adapted in particular to the requirements of friction, to oscillate or overoscillate and its lower part, which has been moving in free space until now, to become attached to the smooth driving roller. Due to the forced movement of the belt further back along the winding bobbin, it now surrounds the smooth driving roller practically along its entire circumference, thus making further oblique running practically impossible. By further dragging together with the movement of the yarn distributor, the belt is subjected to tensile stress so that sooner or later it will break or the related machine components will be damaged.

This disadvantage is essentially eliminated by the device for winding conical or varioconic bobbins, intended in particular for machines with a constant supply of wound yarn, according to the invention, which consists of a drive support roller with a smooth surface, which supports the wound bobbin from below along its width without directly driving it, and of a transmission ring element, which surrounds it in a free loop and which, on the one hand, by frictional contact with the smooth surface of the drive support roller and on the other hand with the outer surface of the wound bobbin, directly forms its drive. The transmission ring element is in this case loosely connected to a guide coupled to the yarn distributor, arranged to be reciprocable along the wound bobbin. The essence of the solution itself lies in the fact that the driving support roller is provided with a transition ring in both areas of change in the angular deflection of the transfer ring element, the diameter of which is different with respect to the diameter of the central part of the driving support roller.

According to one preferred embodiment of the invention, the transition ring is designed such that its diameter increases continuously towards the edge of the drive support roller.

According to another embodiment, the diameter of the transition ring decreases continuously towards the edge of the drive support roller.

The transition ring can be formed as a separate assembly part or as recesses at appropriate locations on the drive support roller.

The greater effect of this arrangement according to the invention lies in the fact that the transition ring assists in the rewinding of the transfer ring element under the casing surface of the bobbin, especially in the first phase of the winding bobbin. This eliminates or significantly suppresses undesirable dynamic stress on the transfer ring element and the elements of the yarn distribution mechanism, which simultaneously form the guide device of the transfer ring element.

The principle of operation and other advantages of the solution according to the invention are apparent from the following description and the accompanying drawings, where:

Fig. 1 is an axonometric view of the device according to the invention with a first exemplary embodiment of the transfer ring;

Fig. 2 shows an axonometric view of the device according to the invention with another exemplary embodiment of the transition ring.

The device for winding conical or varioconical coils shown in Fig. 1 and Fig. 2 consists of a known drive support roller 1 with a smooth surface 11, by which the coil 2 to be wound is supported longitudinally from below without being directly driven by it. The drive of the coil 2 to be wound is directly

244 provides a rotating transfer ring element 3, which is freely suspended on the drive support roller 1 and set into rotational motion by friction against the smooth surface 11 of the drive support roller 1 under the pressure of the wound coil 2.

The rotating transfer ring element 3, which has a larger inner circumference than the outer circumference of the driving support roller 1, is laterally controlled by a guide 4 arranged on the holder 5 of the yarn distributor 6 7. The holder 5 is connected to a distributor rod 10 centrally controlled by a mechanism not shown. The larger inner circumference allows the transfer ring element 3 to be angularly adjustable during rotation, at least in the direction of the guided section 8 of the yarn 7, which leads from the yarn distributor G 7 to the starting point 9 of the yarn 7 on the bobbin 2. The contact of the two bodies, i.e. the transfer ring element 3 and the driving support roller

Claims (5)

1, it is substantially linear in the region of the yarn winding point 9 on the bobbin 2. The linear contact is also in the case of the wrapped coil 2 with the transmission ring element 3, this theoretical line being parallel to the longitudinal axis of the drive support roller 1. During winding of the conical or varioconical bobbin 2, the yarn distributor B is periodically moved along the drive roller 1. This guide 8 angularly deflects the free-hanging rotating transfer ring element 3 into the direction of the guided yarn section 8 by means of guide 4. The transmission ring element 3 is angularly adjusted, retaining its inclined position on the drive support roller 1 during its passage to the second, coil face 2, where by changing the direction of movement of the distributor 6 with the guide 4, it is angularly adjusted again in the other direction thus changing the direction of the guided yarn section 8 to the lead-in point 9 on the bobbin 2. Thus, the guided yarn section 8 is continuously fed to the lead-in point 9 on the bobbin 2 over the surface of the rotating transfer ring element 3. speed, equal to speed of the supplied yarn 7, which is a prerequisite for creating a good quality spool 2. As described above, the rotating transmission element 3 must be angularly adjusted at extreme dead centers by means of a guide 4, in a certain predetermined area on the smooth surface 11 of the drive support roller 1. However, since it is under downforce of either empty tube and bias of the frame, or below the casing surface of the coiled coil 2, its angular adjustment in the known solutions in this area is considerably more difficult. Therefore, according to the invention, the drive support rollers 1 in each region of angular deflection variation of the transfer ring element 3 are provided with a transition ring 12 which continuously increases (Figure 1) or decreases (Figure 2) its diameter towards the edge of the drive support roller 1. FIG. 1 shows an exemplary embodiment of a drive support train 1 in which the diameter of the two transition rings 12 toward the edges of the drive support roll 1 continuously increases to a diameter equal to the sum of the drive support roller diameter 1 and up to twice the thickness of the transfer ring member. 3. In this embodiment, the transmission annular element 3 approaching the extreme dead center, i.e. the point where its angular deflection changes, smoothly approaches the transition ring 12, which tends to return it. This effect begins before extreme dead center, ie in advance. Thus, the transmission ring element 3 is not forced to change its angular deflection and direction of movement by jumping at the extreme dead center, and thus there is no oscillation or overshoot thereof and thus undesirable subsequent phenomena. Thus, the service life of the transfer ring element 3 is substantially increased and the dynamic stress of the entire yarn distribution mechanism is reduced. FIG. 2 shows a further embodiment of a drive support roller 1 in which the diameter of the two transition rings 12 is continuously reduced towards the edges of the drive support roller 1 up to a diameter equal to the difference in diameter of the drive support roller 1 and up to twice the thickness of the transfer ring Element 3. In this embodiment, the transmission ring element 3 approaching the dead center is continuously approaching the transition ring 12, whose decreasing diameter and at a constant speed of the drive support roller 1 decreases its peripheral speed on the basis of generally known physical laws. In this region, the transmission ring element 3 is driven at a higher speed on the side proximal to the center of the drive support roller 1. This force acts on the transmission ring element 3 in vector coincidence with the action of the guide 4 at extreme dead center, but in advance and continuously increasing intensity. This time course of the force actions on the transfer ring element 3 ensures a continuous change of its angular deflection and displacement along the drive support roller 1, thereby increasing its service life and reducing the dynamic stress of the entire yarn distribution mechanism. The adapter ring 12 may be formed as a separate mounting piece, which may be formed on the drive support roller 1, for example by spraying, pouring, or may be formed during manufacture or modification of the drive support roller 1. This adapter ring 12 may also be smooth or provided with longitudinal or transverse grooves. These design modifications will substantially improve the functioning of the entire textile machine winding node, since at the point of contact with the yarn winding point at the leading-in point, the rotating transmission ring element and the drive support roller have the same speed, this speed 26 2? 7, expressed in vector, is perpendicular to the axis of rotation of the drive support roller at all the different positions occupied by the transmission ring element, so that there is relatively quietness at the point of immediate contact of the rotating transmission ring element. A further aspect of this proposed arrangement is that the yarn approaching the inlet point on the bobbin is precisely laid by the transmission ring element so that the surrounding already formed windings of the yarn on the bobbin are not damaged. All of these advantages will have a positive effect when winding conical or varioconical coils. SUBJECT Apparatus for winding conical or varioconical bobbins, in particular on textile machines with a constant supply of winding yarn, consisting of a drive surface support roller with a smooth surface which supports the winding bobbin in width from below without directly driving it and a transfer ring element supporting it in a loose loop and which on the one hand by frictional engagement with the smooth surface of the drive support roller and on the other with the jacket surface of the spool forms the drive thereof, the transmission annular element being hingedly connected to the guide coupled to the yarn distributor. coil, characterized in that the drive support rollers (11) in both regions of the angular deflection change of the transmission ring element (3) are provided with a transition ring (12), the diameter of which is relative to the diameter of the central portion of the drive support (1) different. A device for winding conical or varioconical coils according to claim 1, characterized in that the diameter of the transverse bias (12) increases continuously towards the edge of the drive support roll (11) up to a diameter equal to the sum of the diameter of the drive support roll (12). 1) and up to twice the thickness of the transfer ring element (3). Device for winding conical or varioconical coils according to claim 1, characterized in that the diameter of the transition ring (12) decreases continuously towards the edge of the drive support roller (1) up to a diameter equal to the diameter difference of the drive support roller (1). 1) and up to twice the thickness of the transfer ring element (3). A device for winding conical or varioconical coils according to claim 2 or 3, characterized in that the transition ring (12) forms a separate mounting part. A device for winding conical or varioconical coils according to claim 2 or 3, characterized in that the transition ring (12) forms a recess in the drive support roller (1). 2 sheets of drawings