JP3167567B2 - Multi-color weft insertion device for water jet loom - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a multi-color weft insertion device for a water jet loom, and more particularly to a plurality of weft insertion nozzles corresponding to multi-color wefts and a plurality of weft insertion nozzles provided for each weft insertion nozzle. Pump that operates in conjunction with the main shaft of the loom, a discharge line that branches from the line connecting the weft insertion nozzle and the pump, and a pump that is sent out of the pump in each case when the weft insertion nozzle is selected or not selected. A switching valve for switching the flow path of the water to be supplied, and when the weft insertion of the nozzle is selected, the water supplied from the corresponding pump is supplied to the nozzle side to perform the weft insertion, and when the nozzle is not selected, the water is discharged to the above-mentioned discharge conduit. The present invention relates to an improvement in a weft insertion state in a multicolor weft insertion device of a water jet loom of the following type.

[0002]

2. Description of the Related Art As a multi-color weft insertion device for a water jet loom of the type described above, those disclosed in JP-A-64-6152 and JP-A-3-29344 are known.

In these prior arts, for example, Japanese Patent Application Laid-Open No. 64-6152 uses a plurality of weft insertion nozzles corresponding to the types of weft yarns. Is connected via a water delivery line. A switching valve is provided in the water delivery pipeline, and a water delivery pipeline is constituted by a pump-side pipeline upstream of the switching valve and a nozzle-side pipeline downstream of the switching valve. Further, this switching valve uses a valve that can switch between two positions with three ports, and is connected to a discharge pipe for discharging water to the outside of the system together with the nozzle-side pipe and the pump-side pipe. Further, in Japanese Utility Model Laid-Open No. 3-29344, a two-port on-off valve is used as the switching valve, and the discharge line is branched from the pump-side line, and an on-off valve is further provided in the middle of the discharge line. To switch the flow path.

In the weft insertion device of the above type, when the nozzle is selected for weft insertion, the switching valve is switched so that the pump side line and the nozzle side line are in communication with each other, the discharge line is cut off, and the pump is disconnected from the pump. The water to be sent out is supplied to the weft insertion nozzle from the pump side pipe via the nozzle side pipe.
When the nozzle is not selected, the switching valve is switched to connect the pump side pipe and the discharge pipe, and water is discharged to the outside (tank) through these pipes.

[0005]

However, according to the system configuration of the prior art as described above, air bubbles are generated due to a negative pressure near the discharge port of the pump when water is discharged, At the time of weft insertion immediately after the nozzle is switched from non-selection to selection, there arises a problem that this bubble causes a hindrance to normal weft insertion. The reason will be described below.

The above three pipes have the same diameter. However, on the weft insertion side where water is sent out at the time of weft insertion, the weft insertion nozzle is connected to the downstream end of the nozzle-side pipeline, so that the pipeline is narrowed. However, there is no such constriction in the discharge line from which the water is pumped at the time of discharge. Therefore, the line resistance of the discharge line when discharging water is considerably smaller than the line resistance when discharging water to the weft insertion side. Therefore, the velocity of the water in the discharge line is much higher than the velocity of the water in the nozzle side line. That is, at the time of discharging water, the discharge speed of the pump is increased and the flow velocity in the pipeline is increased because the pipeline resistance is small. For this reason, the water discharged from the pump flows out to the discharge pipe at a considerably higher speed than at the time of weft insertion through a pump-side pipe which is a common pipe with the weft insertion side.

As a result, immediately after the discharge of the pump at the time of discharging water is completed, the vicinity of the discharge port of the pump is instantaneously brought into a negative pressure state due to a large inertial force due to the flow of water at a high speed. Due to this, the air dissolved in the water in the pump side pipe separates, and many bubbles are generated in the water in the pump side pipe which is a common pipe with the weft insertion side. Therefore, the water in the pump-side conduit contains considerably more air bubbles than the state after the end of discharge at the time of weft insertion. When the nozzle is switched from the non-selected state to the selected state under this state, a state in which a number of bubbles are mixed in the conduit on the weft insertion side.

When the weft insertion operation is performed while a large number of air bubbles are mixed in the pipeline as described above, the pressure from the pump is not transmitted normally, and jet water having a pressure necessary for the weft insertion is obtained. Disappears. That is, since the water is usually incompressible, the pressure from the pump is transmitted as it is, so that it is possible to obtain jet water having a pressure necessary for weft insertion. However, in the state where many air bubbles are mixed in the pipeline as described above, the necessary pressure is not transmitted due to the compression of the air bubbles, and therefore, the injection water at the pressure necessary for weft insertion is not obtained, and the injection force is reduced. Connect. In addition, when water is jetted from the weft insertion nozzle, the bubbles in the water compressed as described above are released and spread together with the jet. For this reason, the jet water is dispersed and the convergence is deteriorated, and the drop in the jet force is spurred. When the injection force is reduced in this way, the weft insertion becomes very unstable.

In the nozzle-side conduit, the cross-sectional area of the nozzle and the like are set so that stable weft insertion is performed in consideration of the usual weft insertion conditions, pump operating conditions, and the like. Therefore, as described above, there is no situation in which air bubbles are generated in the pipeline due to negative pressure.

An object of the present invention is to avoid instability of the weft insertion state due to a state in which a large number of air bubbles are mixed in the pipeline as described above.

[0011]

In order to achieve this object, according to the present invention, in a multicolor weft weft insertion device of the type described above, a restricting portion having a cross-sectional area substantially equal to the cross-sectional area of a nozzle is provided in a discharge pipe. It is assumed that it has been established.

[0012]

As a result of the provision of the throttle in the discharge pipe, the state of water flow in the discharge pipe at the time of discharge becomes the same as the state of water flow in the nozzle side pipe at the time of weft insertion. Immediately after the end of the discharge of the pump, the vicinity of the discharge port of the pump does not become a negative pressure state. Therefore, the subsequent weft insertion is performed stably without generating air bubbles in the pump-side pipeline which is a common pipeline with the weft insertion side.

[0013]

FIG. 1 shows an example of a multiple weft selection system for a water jet loom to which the present invention is applied. The weft insertion device in this embodiment includes two weft insertion nozzles (1, 1 ') for wefting two-color wefts and pumps (9, 9') provided corresponding to each nozzle. The nozzle (1, 1 ') includes a nozzle-side pipe (3, 3'), a switching valve (5, 5 '), and a pump-side pipe (7, 7'). It is connected to a pump (9, 9 ') via a water delivery line. Further, a three-port valve is used as the switching valve (5, 5 '), and the switching valve (5, 5') is configured such that the discharge pipe (11, 11 ') branches off from the water delivery pipe. )
It is connected to the. Further, the discharge line (11, 1
The other end of 1 ′) is connected to a constant water tank so that the discharged water is returned to the tank.

When the weft insertion nozzle 1 is selected for weft insertion, the switching valve 5 is switched so that the pump side pipe 7 and the nozzle side pipe 3 are in communication with each other. It is supplied to the weft insertion nozzle via the side conduit 3.
At this time, since the discharge line 11 is blocked, the discharge line 1
No water flows out of the pump to 1. When the weft insertion nozzle 1 is not selected, the switching valve 5 switches the pump side pipe 7 so that the pumping pipe 7 communicates with the discharge pipe 11, and the water discharged by the pump 9 is sent out to the discharge pipe 11.

In the present invention, as shown in FIG. 2, the discharge pipe 11 is provided with a throttle portion 13 having a sectional area substantially equal to the sectional area of the nozzle 1. Therefore, when the nozzle is not selected, the water discharged from the pump is discharged through a pipe whose sectional area is substantially equal to the sectional area of the nozzle. For this reason, water is discharged and discharged in the same state as when weft insertion.

Although not shown, a filter is desirably provided at the downstream end of the discharge line 11 in the present invention. That is, the filter gives a kind of rectifying action to the water, and then discharges the water to the constant level tank. This suppresses the generation of vortices and bubbles in the constant water level tank. In other words, the incorporation of air bubbles into the water sent from the constant water tank to the pump, and hence the incorporation of air bubbles into the water discharged from the pump, is avoided.

By the way, in the above-mentioned throttle portion, the cross-sectional area is set to be substantially the same as that of the nozzle. Since the nozzle diameter is usually in the range of approximately 2-3 mm ² ,
The cross-sectional area of the narrowed portion is also set in this range, at most about 5 mm ² . Further, in the above description, in order to make the line resistance of the discharge line the same as that of the weft insertion side, a throttle portion having the same cross-sectional area as that of the nozzle was provided. The member may be mounted in the conduit.

In the embodiment shown, a throttle is provided at the connection between the discharge line and the switching valve. However, the present invention is not limited to this, and the desired purpose can be achieved regardless of the position in the discharge line.

The switching valve may be either a mechanical drive type (such as a cam) as shown in the figure or an electromagnetic drive type (such as a solenoid). Further, the type of the weft insertion device is not limited to the one described above.
It may be of the type disclosed in US Pat. No. 29344.

[0020]

According to the present invention, the state of the flow of water in the pipeline at the time of discharge is the same as that at the time of weft insertion.
Immediately after the discharge of the pump at the time of discharge is completed, the vicinity of the discharge port is not in a negative pressure state, so that no bubbles are generated in the pipeline and the subsequent weft insertion is very stable.

[Brief description of the drawings]

FIG. 1 is a front view showing the configuration of a multiple weft selection system of a water jet loom to which the present invention is applied.

FIG. 2 is a partially sectional front view showing a main part of the weft selecting device of the present invention.

[Explanation of symbols]

 1, 1 'weft insertion nozzle 3, 3' nozzle side line 5, 5 'switching valve 7, 7' pump side line 9, 9 'pump 11, 11' discharge line

Continuation of the front page (58) Field surveyed (Int.Cl. ⁷ , DB name) D03D 47/32 D03D 47/38

Claims (1)

(57) [Claims] 1. A plurality of weft insertion nozzles corresponding to multicolor wefts, a pump provided for each of the weft insertion nozzles, and operated in conjunction with a main shaft of a loom; A discharge pipe branching from a pipe connecting the same, and a selection valve for switching the flow path of water sent from the pump in each case of selection and non-selection of the weft insertion nozzle,
When the weft insertion nozzle is selected for weft insertion, the water sent from the corresponding pump is supplied to the nozzle side to perform weft insertion, and when the weft insertion is not selected, water is discharged out of the system through the discharge pipe. A multicolor weft insertion device for a water jet loom, characterized in that a throttle portion having a sectional area substantially equal to the sectional area of the nozzle is provided in the discharge conduit.