DE1952829B2 - Density control for the fiber material in a feed chute for feeding a card - Google Patents

Description

The invention relates to a density control for the fiber material in a hopper for feeding a Card with a feed device for the shaft and with at least one movable shaft wall, with forming rollers for guiding the fiber material out of the shaft and for forming the fiber material web, with a measuring device for determining the average density of the fiber material and a drive motor, which can be controlled according to the signals given by the measuring device.

In the production of such fibrous webs on nonwoven machines, the maintenance of a strive for or ensure a uniform fiber fleece thickness or density.

It is known to have the feed chute for the fiber material on one side with a movable side wall to be provided, which is moved by a vibrating roller driven by a motor, one die Density influencing device controls the motor and thereby a corresponding shaking movement on the movable side wall to determine the Density of the fiber material transfers (British patent specification 930 234). However, in this implementation a sufficient and even pre-compaction of the façade material is not achieved because the determination the fiber belt is made by purely mechanical means, which is only very imprecise and with considerable Delay to be able to continuously regulate the density.

ίο In another case that has become known, the density or the thickness of a non-woven fabric measuring device, the finished non-woven fabric between rollers is a Measuring table fed and smoothed on this, with a measurement of the density or thickness of the

Fiber fleece by means of a photoelectric device followed (U.S. Patent 2,466,615). There is no pre-compression of the fiber material or even a density control instead, but by controlling the feed rate accordingly

of the already finished fiber material passing through the rollers is either a thinner or a a thicker fiber fleece is produced, which because of the variable roller speeds different caused in the fiber fleece

Tensile stresses cannot always have a uniformity in density or thickness

There is also a photoelectric measuring device located in front of the nonwoven forming rollers on the feed chute of the fiber material known (French patent specification 972 692). In this execution will be The signals coming from the photocells are transmitted to the forming rollers, which makes them one constantly assume a changed speed of the corresponding fiber material in the feed chute can. By this measure, however, the finished fiber material can only inadequately be more uniform Density can be maintained because of time delays due to the high circumferential forces of the rollers occur between signal occurrence and signal execution, which result because on the one hand for the Deceleration and acceleration of the rollers require a lot of effort and, on the other hand, a certain amount Time is needed. The speed of the roller can never exactly match the conditions be adjusted in the feed chute, so that a uniform density of the fiber material between the Rolling is to be maintained.

The invention is based on the object of a density control for the fiber material in a filling chute for feeding a cord in such a way that a uniform density or thickness of the fiber material is guaranteed and any differences in density that occur can be easily greased as well can be corrected as quickly as possible.

According to the invention, this object is achieved in that the feed chute is followed by a tamper these tamper can be driven by a variable speed motor that as a measuring device for measuring the average fiber density inside a container connected to the shaft a Light source is arranged on one side of the container and that on the other side of the container, the light source opposite one another, a number of known photoelectrical devices, which are arranged at a distance from one another Cells are provided that collect the light emitted by the light source and a electrical signal, which represents an overall result of the photoelectric cells, generate the

Maintaining a substantially uniform density at the container inlet the speed control; changeable drive motor that controls the tamper.
ί The advantages achieved with the invention exist; in particular that the forming rollers at the end of the filling chute are supplied with a uniformly pre-compressed and distributed fiber material, which can be brought into its final shape immediately and in a continuous process, with a uniformly high throughput speed and an increase in the flow quality as well as a particularly high uniformity and density of the fiber fleece. As a result, very tight dimensional and strength tolerances can then be maintained, so that the textile industry has a raw material that is very useful for rapid mass production, namely the manufactured fiber fleece.

An embodiment of the invention is shown in the drawing and is described below. It shows

F i g. 1 is a side view of a nonwoven fabric forming machine to which the invention is applied; F i g. 2 an enlarged schematic representation of the invention,

F i g. 3 one in the direction of arrow 3 in F i g. 2 seen rear partial view of the drive of the Tamper,

F i g. 4 is a schematic diagram of the electrical Control circuit of the invention.

In Fig. 1, the fiber fleece forming machine generally designated 10 is shown in connection with a carding machine generally designated 12. The fiber fleece produced by the fiber fleece forming machine is fed to the card or card by a card feed roller 18. The card generates a fiber fleece W in the usual way, whereupon this is drawn into the spool pot 24 with the aid of a conventional winder 26. Although the card shows a possible use of the fiber fleece, the invention is in no way restricted to a specific use, since the fiber fleece can be used to feed a needle felting machine or any other machine for the production of nonwoven textiles. Nonwoven forming machines are commonly known in the trade as direct cards, chute cards, drivers, mixers, etc.

As in Fig. 1 and 2, pulped fiber material is digested with the aid of a conveyor 28 conveyed from a first container 30. The first container is made of one common fiber 32 designated storage facility supplied. The fibers are removed from the conveyor by a stripper roller 33 removed and dropped into a hopper 34. The conveyor 28 conveys excess fiber, so that the hopper 34 is always filled, while the remaining excess fiber through a return chute 35 is blown to the first container to be conveyed again by the conveyor 28 to become.

The hopper 34 includes a fixed plate 36 and an oscillating plate 38 which are designed to move downward of the fibers and for a uniform width distribution of the fiber material in the machine and also supplies the fiber web molding machine 10 with a largely uniform density.

As can be seen particularly from FIG. 2, the nonwoven fabric forming machine 10 includes a pair of darning rollers 40 which feed a second container 46 through an inlet 44. The rollers 40 stuff the fibers into the container 46. With the aid of a pair of nonwoven forming rollers 48, fibers are drawn out of an outlet 50 of the container 46 and fed to the card feed rollers 18. The fiber fleece forming rollers and the feed rollers 18 are driven synchronously and in the same way, so that if the fiber density is kept constant at the outlet 50 of the container 46, a constant amount of fiber is conveyed by the fiber fleece forming rollers 48, which leads to the production of a uniform fiber fleece.

In order to maintain a uniform fiber density in the container 46, devices are provided. hen that control the rotation of the darning rollers 40. As shown in FIGS. 2 and 3, is a variable speed Drive motor 51 connected as a drive to one of the tamping rollers, which in turn a toothed gear 52 of the same module is connected to the other tamping roller, so that the tamping rollers 40 driven synchronously and in opposite directions, as indicated by arrows 55 in FIG. 2 show.

The speed of the motor is dependent on the average density of the fibers in the container 46 controlled. F i g. 2 z ^ ig on one of the ropes of the container 46, a dust-free housing 56 and a dust-free housing 58 on the other side. A number Photoelectric cell 54 is arranged in the housing 56 to be illuminated by a light source 60 in the housing 58 to collect emitted light. The parts of the housings 56 and 58 that are adjacent to the container 46, consist of transparent or translucent material 62, such as glass or the like.

The circuit for controlling the speed of the drive motor 51 is shown in FIG. The drive motor lies between two current-carrying conductors 64 and 66. The current flow through the armature The drive motor is controlled by a silicon rectifier, which is in the conductive state feeds the positive half of the oscillation of each electrical pulse to the drive motor. An ignition circuit 70 works synchronously with the rectifier 68 and controls the ignition angle of the rectifier 68 in the Way that the one becomes longer or shorter during the positive half-oscillations around the motor supply more or less electricity. This part of the engine control is standardized and in general Electric Manual GEK-4660 from May 1967 neari described.

So the normal engine control circuit also includes a manually controlled potentiometer 72 which provides a reference voltage. This reference voltage is constant for a given engine speed. Generated during the negative half-cycle, in which the rectifier 68 is not permeable The DC motor produces an electromotive force (EMF) that changes with the engine speed. Of the Ignition circuit compares and receives the difference between the EMF and the reference voltage essentially constant by changing the ignition angle of the rectifier 68. The engine speed drops below a predetermined speed, the generated EMF drops, whereby an increase in the Difference between the reference voltage and the EMF. The ignition circuit 70 reacts to this difference by bringing the ignition angle of the rectifier 68 forward so that this during every half oscillation remains more permeable, where-

if more current is supplied by the armature and to measure density in the container 46, this is done by the the engine speed increases. Is the motor speed cell outgoing signal through the hand paid above the predetermined speed, the activated speed control 72 output signal increases EMK on, resulting in a decrease in the pulse. When the density of the between the light source difference between the reference voltage and the fiber material passing through the cells ab-EMF is caused. In response to this decrease, the stronger incidence of light causes a greater difference the ignition circuit 70 responds by delaying the delivery of current to the cells. This enlarged ization of the firing angle of the rectifier 68, so the difference between the current output increases that this short-term cell signal and the EMF with every half oscillation. The ignition circuit reacts * permeable isi, which means that the armature has less current io due to this difference by moving the armature forward receives and the engine speed drops. The reference firing angle of the rectifier 68. which is the motor voltage the potentiometer can be used to reduce the speed by hand. The increased engine speed causes to set the speed as required: faster rotation of the tamping rollers, where-

In contrast to the normal circuit for the Mo- through more material between the light source and

gate speed control, with which the engine speed 15 is passed through the cells,

can be kept constant, the in Fi g. 4 due to an increased material density between the

set control circuit for the motor speed in the light source and the photocells, the current

has been modified in such a way that the turning ability of the cells is diminished. The degradation of the

The number of the motor can be changed automatically to deliver a current of the cells reduces the difference

Maintain a specified density of the material. 20 between the cell signal and the EMF. Demented

In the modified circuit of the invention, speaking, the ignition circuit delays the ignition angle

novb rv.-ei signals are included that affect the ignition circuit of rectifier 68, which decreases the mo-

are fed. One of the signals is the EMF, which results in door speed. This will make the

while the other of the photoelectric cells turns the darning rollers more slowly, and it becomes less

54 is generated. The photocell signal is amplified 25 Faber material between the light source and the cell

and replaces the one mentioned above, brought by hand by Jen.

set reference voltage. The cells become it i ^ t of importance that what is produced by the cells

excited by the light, which signal held by the light source for the mean fiber density within

Starting from 70, irradiates the container 46. The er- a cut through the entire width of the container

Activation of the photocells causes a signal which is characteristic of 30 years 46. This is why

is amplified by an amplifier circuit 74. When there are a number of cells that are larger than the

Cells 54 are photocells with the outer width of the container are distributed so that

Lichielektischpii LT!> k if excited 'njrch each of the cells receives light from the light source 60

Lioh'energie eiuen '' emit a current. It can begin, which passes through another section of the

Resistance cells can also be used when the container 46 has passed through. Now step between

which the resistance varies depending on the density of the two ends of the container.

changing the light. If the latter is explored, the cells are divided into different

which is a separate source of energy, but excites both to a certain extent. The current output of all cells

Types produce a light intensity proportional to a single display, see that

tional small stream. 4 ° the resulting signal is therefore an image of the

The circuit shown in FIG. 4 can represent medium fiber density over the container 46. Operated manually or automatically. With the help of the light source 60 can be selected from a number of a double pole in the form of a double switch 75, lamps, one for each photocell, or off which has two switch arms 76 »md 77, which can consist of a fluorescent light source, which Sounding can then be operated by hand when 45 is over the entire translucent surface 62 de «·. the arms 76 and 77 in which in FIG. 4 in the extended housing 58 emits a homogeneous light. If crnem Line shown are position. If desired, the intensity of the light source can be adjusted with Circuit is closed in this way, the machine can use a conventional intensity control circuit can be operated manually in order to change the engine speed, denoted by 80 in FIG Change until the desired density of the fiber is 50. The light intensity can therefore depend on For this motor speed, the type of fiber used or the associated, manually controlled reference tension in the density of the generated fiber fleece increases or unites Matching circuit 78 entered. Which are diminished by.

The reference voltage obtained from the photocells 54 is sent. The amplified signal is also sent to the matching circuit by means of a sensor. The 55 possibility control circuit 83 sent, which to distinguish between these reference voltages, changes in the photo telecom input to the ignition circuit are displayed on a voltmeter, which can be set on the frontal signal. The switching side of a switchboard is arranged. The value of the circle 83 controls the speed with which the Mo-cell signal is changed ^c o long until it matches exactly gate speed depending on changes in the manually entered reference signal over- δο photoelectric signal enlarged or reduced, so that the voltmeter a difference of will. It can display any normal sensitivity level of volts. If the signals are used in this way management circuit, the two hand-operated have been adapted, the Schalte.arme 76 potentiometers can contain the charging and 77 of the switch 75 in Fig. 4, the dashed discharge speed of a capacitor to be shown position brought, whereby the circuit 65 correct,
is switched to automatic. The electrical control device described

When the circuit in FIG. 4 to automatic - offers a high degree of adaptability, so that

has been made to reflect the changes in fiber- they apply to a wide range of fiber and fiber-

^ adjustable fleece conditions. She is so sensitive that even very slight changes in the engine speed within very short time intervals can be brought about. When operated with a current of 60 Hz, for example, the silicon

rectifier sixty pulses supplied to the motor, each of which by the intensity of the photocell signal is affected. Any change in fiber density measured across container 46 has an effect inevitably on the engine speed.

1 sheet of drawings

Claims (3)

Patent claims: 1. Density control for the fiber material in a feed chute for feeding a card with a Feed device for the shaft and with at least one movable shaft wall Forming rollers for guiding the fiber material out of the shaft and for shaping the fiber material web, with a measuring device for determining the average density of the fiber material and eipem drive motor, which corresponds to that of the signals given to the measuring device can be controlled, characterized in that cLm Filling chute (34) pusher downstream and this pusher from a motor (51) with changeable Speed can be driven that as a measuring device for measuring the average fiber density in the Inside a container (46) connected to the shaft (34), a light source (60) on one side of the container is arranged and that on the other side of the container, the light source (60) opposite, a number of spaced apart, known per se photoelectric Cells (54) are provided which capture the light emitted by the light source and a generate an electrical signal representing an overall result of the photoelectric cells, that to maintain a substantially uniform density at the container outlet (50) the variable-speed drive motor (SI) controls the tamper. 2. Device according to claim 1, characterized in that the photoelectric cells and the light source is housed in transparent, dust-free housings (56, 58). 3. Device according to claim 1, characterized in that the stuffer in the form of tamping rollers (40) are formed.