WO2005052233A1 - Thread control device for a textile machine in particular for a shedding device - Google Patents

Abstract

The invention relates to a thread control device for a textile machine, in particular, for a shedding device, with at least one thread guide body (31) which may be displaced in one displacement direction by means of a positive drive (35) and in the opposite direction by means of a non-positive, pneumatic return device (36). The return device (36) thus comprises a cylinder/piston unit (64,54), the cylinder chamber of which (52) is connected to a compressed gas source (60) by means of a valve (56). An improvement in control is achieved when the valve (56) comprises a first valve seat (72) connected to the cylinder chamber (52) and a second valve seat (76), between which a valve body (82), provided with at least one throttle point (80), may be displaced, pre-tensioned in the rest position by means of a spring (84) against the first valve seat (72), in which the throttle point (80) is ineffective and the valve body (82) blocks the communication with the compressed gas source (60) when the valve body (82) is in contact with the second valve seat (76).

Description

 Thread control device for a textile machine, in particular for a color forming device

Technical field

The invention relates to a thread control device of a textile machine, in particular for a shedding device according to the preamble of claim 1.

State of the art

Thread control devices for textile machines are known in large numbers. The closest prior art according to WO 97/08373 discloses a thread control device which is designed with a drive and a retraction device for a thread guide member. The thread guide member can be moved in one direction of movement by means of the form-fitting drive and in the opposite direction by means of a force-fitting and pneumatically designed retraction device acting against the form-fitting drive. The pneumatic retraction device has a cylinder / piston unit, the cylinder chamber of which is designed with a pressure relief valve and a check valve which is connected to a compressed gas source. The gas pressure in the cylinder chamber is set depending on the operating state of the textile machine. For example, in a crawl gear phase, the gas pressure is kept lower than in a high-speed phase, so that the electric motor can provide the power required to overcome the load resulting from the compression of the cylinder chamber. In a high-speed phase, the electric motor delivers sufficient power so that the gas pressure can be increased further to prevent a roller from lifting off on a cam disk of the positive drive. Furthermore, the cylinder chamber can be designed with a manually operable pressure relief valve in order to minimize the resistance created by the compression of the cylinder chamber when the textile machine is being set up. A disadvantage of the above solution is that the gas pressure in the cylinder chamber has to be adapted to a particular operating state. This requires a complex pressure control device for adjusting the gas pressure of the cylinder chamber, which pressure-reducing valves and opening valves make it necessary to control each cylinder chamber. In addition, complex electronic control of the valves is necessary in order to adapt the pressure in the cylinder chambers to a particular operating state.

To lubricate the cylinder / piston unit, oil drips onto the piston from above, for example, and enters the cylinder chamber due to hydrodynamic effects despite constant overpressure in the cylinder chamber. The oil accumulated in the cylinder chamber can permanently disrupt the operation of the thread control device because it reduces the air volume in the cylinder chamber to an undetermined level, which in operation leads to higher, unpredictable compression pressures in the chamber. In extreme cases, where a large part of the cylinder chamber is filled with oil, it is no longer possible to move the cylinder and further operation of the textile machine would lead to considerable damage.

In an improved embodiment of the pneumatic retraction device described in WO 97/08373, the valve is therefore designed in such a way that oil separation is also possible in addition to the requirements of stationary operation. The valve is actuated at regular time intervals for a few seconds in order to drain the oil that has accumulated in the compression chamber. To avoid lifting the roll from the eccentric of the positive drive, the speed of the textile machine must be reduced during this process (so-called care cycle). It is also opened in the creep speed so that the pressure in the cylinder chamber does not rise significantly above the feed pressure. This reduces the power required by the motor, which is necessary so that the main motor can run smoothly at low speeds and so that manual turning on the handwheel is possible without too much effort. A disadvantage of the above solution is the great effort for the electrical / pneumatic control of the valve. The entire control of the pneumatic drive of the thread control device therefore has a large number of components, such as check valves, pressure relief valves, pressure reducing valves, and electronic control units, which make the system more susceptible to faults. In addition, the economy of the textile machine is reduced by the repeated lowering of the engine speed every 15 minutes to drain the lubricating oil. Lowering the engine speed can also have a negative impact on the weaving quality, for example, it can lead to a slight change in the width of the fabric being produced.

Presentation of the invention

The object of the invention is to improve a thread control device of the type mentioned at the beginning.

The stated object is achieved by the characterizing features of claim 1. Characterized in that the valve has a first valve seat connected to a cylinder chamber and a second valve seat, between which a valve member provided with at least one throttle point and biased with a spring against the first valve seat can be moved, the throttle point being ineffective and the valve member communicating with the compressed gas source blocks, when the valve member is in contact with the second valve seat, the valve can work in different operating states without external control. Furthermore, a reliable oil separation without lowering the speed, a reduction of the maximum compression pressure in the cylinder chamber at partial load, as well as a lowering of the compression pressure to feed pressure in the creeper gear without additional measures is guaranteed by the autonomously working valve.

Advantageous embodiments of the invention are described in claims 2 to 19. In principle, a wide variety of embodiments of the valve designed with two valve seats are conceivable. An embodiment according to claims 2 and 3 is advantageous, according to which the housing has two parts, one part having the first valve seat at one end and the other being designed as a closing part of the housing with the second valve seat and a through-channel. The valve therefore has the simplest possible construction, which allows inexpensive production and simple assembly of the valve.

The valve housing can fundamentally have different shapes, a cylindrical design of the housing according to claim 4 is advantageous. This design allows the piston-like valve member to be guided well in the housing. The piston-like valve member can also be provided with a sealing ring in order to seal the cylinder chamber from the outside. In the embodiment according to claim 4, it is advantageous to design the throttle points as throttle openings formed on the valve member. According to claim 5, it is also conceivable to design the valve member without a sealing ring, wherein a gap between the valve member and the housing wall can serve as a throttle point.

The valve can be arranged in a connecting line between the cylinder chamber and the feed pressure chamber. However, a direct arrangement in the cylinder of the cylinder / piston unit is advantageous. According to claim 7, it is also advantageous to arrange the valve at a lowermost position of the cylinder. The valve can thus communicate directly with the cylinder chamber and lubricating oil accumulated in the cylinder chamber can thus be guided through the valve into the feed pressure chamber in a short way. Accordingly, the end part of the valve is directly connected to the feed pressure chamber according to claim 8, in order to minimize the flow resistance and the flow path of the oil flowing away.

The feed pressure chamber can basically have any configuration. An embodiment according to claims 9 to 12 is advantageous, where after the feed pressure chamber is formed with an outlet arranged at its bottom for the oil separation and after which a connection for compressed air can be arranged on a side wall at a distance from the bottom of the feed pressure chamber. This arrangement of compressed air connection and oil separation outlet prevents oil that has accumulated in the feed pressure chamber from clogging the compressed air connection or flowing into a connecting line of the compressed air connection. In principle, each retraction device can have a separate feed pressure chamber. However, it is advantageous to connect a plurality of retraction devices with one feed pressure chamber. This enables a simple construction with only one connection for the compressed air and only one outlet for the oil separation for several retraction devices.

In principle, a wide variety of designs of the pneumatic retraction device according to the invention are conceivable. A particularly simple embodiment of the valve is described in claims 13 to 16, the valve in connection with claims 5 and 6 being able to be arranged in a lower position of the cylinder chamber of the cylinder / piston unit. According to claim 13, a lower portion of the cylinder can serve as a housing for the valve. The valve chamber can advantageously be delimited by the inner surface of the cylinder, by a closing part which closes off the cylinder chamber and by a valve member and can be connected directly to a compressed gas source via a connection arranged on the cylinder wall. A first valve seat for the valve member can be formed on an annular stop. According to claim 15, a second valve seat can be formed on a sleeve part of the end part. If the valve member moves against the second valve seat, the communication between the cylinder chamber and the compressed gas source is blocked and the throttling points on the valve member become ineffective. In addition, it is particularly advantageous to arrange an outlet for oil separation directly on the end part according to claim 16. The valve is activated as soon as the pressure in the feed pressure chamber exceeds the switching pressure. The latter depends both on the pressure of the feed pressure chamber and on the biasing force of the spring. An embodiment according to claims 17 and 18 is advantageous, according to which the pretensioning force can be adjusted from the outside, for example, by means of a screw.

The maximum compression pressure of the valve is adjustable by means of the flow cross section of the throttle point according to claim 19. If a higher compression pressure is required, the flow cross-section of the throttle point is reduced. Due to the smaller throttle area, communication between the cylinder chamber and the compressed gas source is interrupted earlier, which means that a higher maximum compression pressure is achieved.

The switching pressure and the maximum compression pressure in the cylinder chamber can be set in a simple manner by means of the embodiments according to claims 17 to 19.

Brief description of the drawings

Exemplary embodiments of the thread control device according to the invention are described in more detail below for an IM needle ribbon weaving machine with reference to the drawings, in which:

Figure 1 is a side view of a needle ribbon loom; FIG. 2 shows a shaft device with a pneumatic retraction device in a view transverse to the running direction of the warp threads; Figure 3 shows the pneumatic retraction device shown in Figure 2 in a cutout and on a larger scale in the basic position; Figure 4 shows the pneumatic retractor shown in Figure 3 in the compression position;

Figure 5 shows another embodiment of a pneumatic retraction device on a larger scale; Figure 6 shows the pneumatic retractor shown in Figure 5 in the compression position; FIG. 7a pressure and piston profiles of the pneumatic retraction device according to the invention in the crawl gear; FIG. 7b pressure and piston profiles of the pneumatic retraction device at partial load; and FIG. 7c pressure and piston profiles of the pneumatic retraction device at full load.

Ways of Carrying Out the Invention

1 shows a needle ribbon loom with a machine frame 2, in which a main drive shaft 4 is mounted, which drives at least one weft needle 6, a reed 7, a fabric take-off 8 and a thread control device designed as a shaft device 10. The needle ribbon loom has a warp beam frame 12 which carries warp beams 14, of which warp threads 16 are fed to the shaft device 10, which opens the warp threads to a shed 18. By means of a thread feed device 20, a weft thread 24 is fed from a thread bobbin 22 to the weft needle 6 and introduces a weft thread loop into the shed 18. Successive weft thread loops can be tied with themselves or by means of a catch thread 26, which is fed via a further thread feed device 28 to a knitting needle, not shown here, in order to tie off a registered weft thread loop and to secure it.

2 shows the shaft device 10, in which several shaft frames 30 with thread guide members 31 are each connected by means of a link 32 on the one hand via a positive drive 35 to a cam drive 34 and on the other hand to a pneumatic retraction device 36. The cam drive 34 has swivel levers 38 which cooperate with cams 42 of a camshaft 44 at a drive point 40. At the output point 46, the pivot levers 38 are articulated to the links 32 via joints 48. The pivot axes given by the joints 48 run at right angles to the planes spanned by the shaft frame 30. The distances A between the pivot levers 38 of the drive points 40 and the respective pivot axes 50 are different between adjacent pivot levers, the distances B between the output points 46 and the fixed pivot axes 50 also being different, the whole in such a way that the shaft frames are of different sizes Lines are displaceable to form a continuously expanding and narrowing shed, as can be seen from FIG. 1. The pneumatic retraction device 36 is formed by a cylinder chamber 52 in which a piston 54 is displaceable, which is connected to the link 32 in order to positively compress the piston in the working frequency of the cam drive 34. The cylinder chamber 52 is connected to a valve 56. The latter is preceded by a feed pressure chamber 58, via which a compressed gas source 60 is connected in order to maintain the gas pressure in the cylinder chamber 52.

Figure 3 and Figure 4 show the pneumatic retraction device on a larger scale during a compression process. 3 shows the piston 54 at an upper dead center 66 and FIG. 4 the piston 54 at a lower dead center 68 in a cylinder 64 after the compression. The valve housing consists of two parts, a sleeve-like housing 70 with a first valve seat formed at one end 72, which is connected to the cylinder chamber 52 and a closing part 74, which has a second valve seat 76 and a through channel 78. The latter is connected to the feed pressure chamber 58. A valve member 82 provided with throttling points 80 is movably arranged between the valve seats.

In the initial state of FIG. 3, the valve member 82 is biased against the first valve seat 72 by means of the biasing force of a spring 84, so that the cylinder chamber 52 and the feed pressure chamber 58 are in communication with one another via the throttle points 80 in the valve member 82 and the through-channel 78 of the end part 74 , At high pressure in the cylinder chamber 52, the valve member 82 moves against the second valve seat 76 and interrupts communication between the cylinder chamber 52 and the feed pressure chamber 58, as shown in FIG. 4. In this position the throttling points 80 are ineffective.

The compression / expansion process of the cylinder / piston unit is described below with reference to FIGS. 3 and 4 and in connection with the diagrams of FIGS. 7a, 7b and 7c. In the latter, H stands for the stroke of the piston of the cylinder / piston unit with UT as bottom dead center and T T as top dead center and PK for the pressure of the gas in the cylinder chamber. PS represents the switching pressure necessary for the valve member to switch from the first to the second valve seat or from the second to the first valve seat. The switching pressure PS can be divided into the feed pressure PD of the compressed gas source and the corresponding pressure PF of the spring force. VZ represents the position of the blocked and VO that of the valve communicating with the cylinder chamber via the throttle points.

First, the piston 54 moves from top to bottom in the cylinder 64 and, in a first phase, displaces air through the throttle points 80 formed on the piston-like valve member 82 against the feed pressure chamber 58. As the piston speed increases, the pressure difference (PK-PD) across the valve member 82 increases until the switching force generated by the cylinder chamber pressure PK on the valve member 82 overcomes the biasing force of the spring 84 and the force generated by the feed pressure PD on the valve member 82, and presses the valve member 82 against the second valve seat 76. The throttle point 80 of the valve member 82 is no longer effective. By further moving the piston 54 against the valve 56, the cylinder chamber pressure PK rises sharply during the compression process in the cylinder chamber 52 and reaches its maximum at the bottom dead center UT. In the expansion phase, the valve member 80 moves from the second to the first valve seat 76 as soon as the spring force exceeds the force generated by the pressure difference (PK-PD) on the valve member 80. At the end of the expansion phase, which corresponds to the top dead center 66 of the piston, the feed pressure PD is established in the cylinder chamber. In addition, any oil that may have accumulated in the cylinder chamber 52 can now drain through the passage 78. In a next compression process, the outflowing oil is blown out by the air displaced into the feed pressure chamber 58 and flows out in an outlet 88 formed on a bottom 86 of the feed pressure chamber for oil separation. A connection 90 for compressed air is arranged on a side wall 92 of the feed pressure chamber, and thus prevents the oil from flowing back further.

FIG. 5 and FIG. 6 show a further embodiment variant of a pneumatic retraction device on a larger scale during a compression process. 5 shows the piston 54 again at an upper dead center 66 and FIG. 6 shows the piston 54 at a lower dead center 68 in the cylinder 64 after the compression of the cylinder chamber 52 , The wall of the cylinder serves as a valve housing and a valve chamber 94 is delimited by the wall of the cylinder 64, a closing part 74a which closes the cylinder 64 and a piston-like valve member 82a. A stop 71 designed as a ring is arranged directly in the interior of the cylinder 64 of the cylinder / piston unit and serves as a first valve seat 72a for the piston-like valve member 82a. The latter is in turn biased against the first valve seat 72a by a spring 84a. The spring 84a is supported on the end part 74a closing the cylinder, which has an inner sleeve part 96 for guiding the spring 84a and whose free end also serves as a second valve seat 76a for the valve member 82a. If the latter strikes the second valve seat 76a, the throttle point 80a formed in the valve member 82a becomes ineffective. Likewise, in this position, a connection 90a arranged on the cylinder for a compressed gas source 60 is blocked by means of the valve member 82a. Oil accumulated in the cylinder chamber 52 can flow out via an outlet 88a for oil separation formed on the end part 74a.

In the initial state of FIG. 5, the valve member 82a is biased against the first valve seat 72a by means of the biasing force of the spring 84a, so that the cylinder chamber 52 is connected to a compressed gas source via the throttle points 80a Valve member 82a communicate. At high pressure in the cylinder chamber 52, the valve member 82a moves against the second valve seat 76a and interrupts the communication between the cylinder chamber 52 and the compressed gas source 60 by blocking the connection 90a arranged in the cylinder wall, as shown in FIG. In this position, the throttling points 80a are ineffective.

At the end of an expansion phase, 52 feed pressure is established in the cylinder chamber. Any oil that has accumulated in the cylinder chamber 52 can now flow through the throttling points 80a into the valve chamber 94. In a next compression process, the outflowing oil is blown out by the air displaced into the valve chamber 94 and flows out in the outlet 88a formed on a bottom 98 of the end part 74a for oil separation. The connection 90a for compressed air is arranged on a wall 100 of the cylinder at a distance from the bottom of the closing part, and thus prevents the oil from flowing back further.

FIGS. 7a, 7b and 7c show the pressure and piston profiles of the retraction device according to the invention over two load cycles in the creeper gear for a speed of 800 rpm (FIG. 7a), for partial load at 1000 rpm (FIG. 7b) and for full load 4000 U / min (Figure 7c) shown.

In the crawl speed up to an operating speed of, for example, 800 rpm (FIG. 7a), pressure compensation takes place continuously via the throttling points of the valve member, so that the cylinder pressure PK does not reach the switching pressure PS required to interrupt communication between the cylinder chamber and the compressed gas source. The pressure in the cylinder chamber PK is therefore always in the order of the feed pressure PD. The load on the motor caused by the pneumatic drive is consequently low and enables the motor to run smoothly and, in particular when the drive is switched off, the thread control device is moved by hand, for example for setting and repair purposes. At partial load of 1000 rpm (FIG. 7b), the cylinder chamber pressure PK reaches the required switching pressure PS during a cycle, whereupon the valve blocks the communication of the compressed gas source with the cylinder chamber and the compression in the closed cylinder chamber begins. The compression in the cylinder chamber reaches its maximum at a bottom dead center UT. With subsequent expansion, the cylinder chamber pressure PK again falls below the switching pressure PS. The cylinder chamber is now in connection with the compressed gas source again and when the piston reaches an upper dead center TDC, supply pressure PD is established again in the cylinder chamber. The compression pressure in the cylinder chamber prevents the roller from lifting off the eccentric of the positive drive at higher operating speeds.

At full load of 4000 rpm, the required switching pressure PS is reached earlier (Figure 7c) than at lower operating speeds. The compression therefore takes place over a larger stroke and consequently the maximum compression pressure reaches a higher value than at lower operating speeds. In the subsequent expansion, the necessary switching pressure PS is again reached, whereupon the valve restores the communication of the cylinder chamber with the compressed gas source. The maximum compression pressure is a direct function of the speed of the machine, i.e. the maximum compression pressure increases with higher speed. This is advantageous both for economical operation of the machine and for the correct operation of the positive drive.

By opening the valve once per work cycle, the lubricating oil accumulated in the cylinder chamber flows away continuously. This enables the system to be operated safely and continuously, without any maintenance cycles for removing the lubricating oil from the cylinder chamber. The tasks and requirements for the valve described above are autonomous, ie without any external control. Due to the dimensioning of the spring force, the throttle cross-section and the valve autonomous control functions of the valve are given.

The retraction device for a found control device described here thus autonomously fulfills a wide variety of requirements and at the same time has a minimal technical effort. The retraction device is therefore particularly inexpensive to manufacture and its operation is largely maintenance-free and trouble-free due to its simple structure.

The thread control device according to the invention can also be used for a single thread control, for example for a jacquard machine, furthermore in a weft thread device for feeding individual weft threads.

Bezuσszeichenliste

2 machine frame 56a valve 4 main drive shaft 35 58 feed pressure chamber 5 6 firing needle 60 pressurized gas source 7 reed 64 cylinder 8 fabric take-off 66 top dead center 10 shaft device 68 bottom dead center 12 warp beam frame 40 70 housing

10 14 warp beam 71 stop 16 warp thread 72 first valve seat 18 shed 72a first valve seat 20 thread feed device 74 end part 22 thread bobbin 45 74a end part

15 24 weft 76 second valve seat 26 catch thread 76a second valve seat 28 thread feed device 78 through channel 30 shaft frame 80 throttle point 31 thread guide member 50 80a throttle point 0 32 link 82 valve member 34 cam drive 82a valve member 35 - positive drive 84 spring 36 retraction device 84a spring 38 pivoting lever 55 86 bottom 5 40 Drive point 88 outlet 42 cam 88a outlet 44 camshaft 90 connection 46 output point 90a connection 48 joint 60 92 wall 50 pivot axis 94 valve chamber 52 cylinder chamber 96 sleeve part 54 piston 98 bottom 56 valve 100 wall

Claims

claims

1. Thread control device for a textile machine, in particular for a shedding device, with at least one thread guiding element (31) which can be moved in one direction of movement by means of a form-fitting drive (35) and in the opposite direction of movement by means of a non-positive and pneumatically designed retraction device (36), the latter having a cylinder / piston unit (64, 54), the cylinder chamber (52) of which is connected to a compressed gas source (60) via a valve (56, 56a), characterized in that the valve (56, 56a) has a first one having a valve seat (72, 72a) connected to the cylinder chamber (52) and a second valve seat (76, 76a), between which a valve member (82, 82a) provided with at least one throttle point (80, 82a) can be moved, which in the basic position can be moved by means of a spring (84, 84a) is biased against the first valve seat (72, 72a), the throttle point (80, 80a) being ineffective and the valve member (82, 82a) the Communication with the compressed gas source (60) blocks when the valve member (82,82a) is applied to the second valve seat (76,76a).

2. Thread control device according to claim 1, characterized in that the valve has a housing (70), at one end of which the first valve seat (72) is formed.

3. Thread control device according to claim 2, characterized in that the second valve seat (76) is formed on a with a through-channel (78) formed end part (74).

4. Thread control device according to one of claims 2 or 3, characterized in that the housing (70) is cylindrical, in which the piston-like valve member (82) is guided sealed against the housing wall.

5. Thread control device according to one of claims 2 or 3, characterized in that a gap between the valve member (82) and the housing wall of the valve (56) serves as a throttle point.

6. Thread control device according to one of claims 1 to 5, characterized in that the valve (56,56a) is arranged in the cylinder chamber (52).

7. Thread control device according to one of claims 1 to 6, characterized in that the valve (56, 56a) is arranged at the lowest point of the cylinder (64).

8. Thread control device according to one of claims 1 to 7, characterized in that the end part (74) of the valve (56) is connected directly to a feed pressure chamber (58).

9. Thread control device according to claim 8, characterized in that the feed pressure chamber (58) has an outlet (88) for oil separation for an oil from the cylinder chamber (52).

10. Thread control device according to claim 9, characterized in that the outlet (88) for the oil separation is arranged on a bottom (86) of the feed pressure chamber (58).

11. Thread control device according to claim 10, characterized in that a connection (90) for compressed air on a side wall (92) of the feed pressure chamber (58) is arranged at a distance from the bottom (86) of the feed pressure chamber.

12. Thread control device according to one of claims 8 to 11, characterized in that the feed pressure chamber (58) serves at least one retraction devices (36) as feed pressure and oil drain device.

13. Thread control device according to claim 1, characterized in that a lower portion of the cylinder (64) serves as a valve housing and has a connection (90a) for the compressed gas source (60).

14 thread control device according to claim 13, characterized in that an annular stop (71) is arranged inside the cylinder (64) and this is designed as the first valve seat (72a) connected to the cylinder chamber (52).

15. Thread control device according to claim 14, characterized in that the cylinder (64) is closed off by means of the end part (74a), the latter having a sleeve part (96), the free end of which serves as a second valve seat (76a).

16. A thread control device according to claim 15, characterized in that an outlet (88a) for the oil separation is arranged on the end part (74a).

17. Thread control device according to claim 1, characterized in that 0 the switching pressure (PS) of the valve (56, 56a) is adjustable by changing the biasing force of the spring (84, 84a).

18. Thread control device according to claim 17, characterized in that the biasing force of the spring (84,84a) is adjustable from the outside. 5 19. Thread control device according to claim 1, characterized in that the maximum compression pressure (PK) of the cylinder chamber (52) by means of the flow cross section of the throttle point (80, 80a) is adjustable. 0