Electricity: electrical systems and devices – Control circuits for electromagnetic devices – Systems for magnetizing – demagnetizing – or controlling the...
Reexamination Certificate
2001-10-12
2004-08-03
Dinkins, Anthony (Department: 2831)
Electricity: electrical systems and devices
Control circuits for electromagnetic devices
Systems for magnetizing, demagnetizing, or controlling the...
C361S154000, C361S091200, C361S160000, C361S172000
Reexamination Certificate
active
06771479
ABSTRACT:
BACKROUND OF THE INVENTION
This invention relates to a device for energising a number of solenoids of a hook selection device for a weaving machine, comprising an electrical power supply source connected to the solenoids and a regulating device for regulating the current intensity in the solenoids.
This invention relates in particular to a device with which the current intensity in the solenoids is regulated in order to control the electromagnetic force the solenoid is exerting on the respective hooks.
Furthermore this invention also relates to a hook selection device for a weaving machine, which comprises such a device for energising a number of solenoids acting on hooks. A jacquard machine or a weaving machine that comprises such a hook selection device of course also falls within the scope of this invention.
From EP 0 188 074 a hook selection device for electronically controlled jacquard machines is known. This device comprises a series of flexible hooks of ferromagnetic material that are provided with an opening and a number of solenoids disposed in solenoid housings.
Each hook is opposite a solenoid housing and can be taken by a knife, that is moving up and down, to a position whereby the opening comes to stand in front of a projection provided at a fixed height. When a solenoid is energised, the hook is attracted. Because of this the projection arrives in the opening and on the subsequent downward movement of the knife, the hook remains hooked on to the projection. In this position the hook is selected.
In each solenoid housing one or two solenoids with iron core and pole plates are provided. When the hook is in front of the solenoid and the solenoid is not energised then there is a sufficiently large air gap between the hook and the pole plates in order that the hook does not hook on to the projection due to the effect of vibrations. In this position the hook is not selected and the hook will therefore move back down with the descending knife.
In order to select the hook the solenoid must therefore be capable of attracting a flexible spring hook of ferromagnetic material over a rather large air gap. The electromagnetic force required will therefore have to be sufficiently great. This electromagnetic force is proportional to the electromagnetic flux that is generated by the solenoid. The electromagnetic flux is proportional to the number of Ampere turns of the solenoid. The solenoid is energised by an electric voltage supply that is switched on or off by a switching transistor under control.
When applying an electric voltage to the solenoid the electric current in the circuit increases exponentially from a zero value until the regime current value is reached. When the electromagnetic flux has become sufficiently great in order to overcome the initially large air gap the hook will bend in order to lean against the solenoid housing. The energising of a solenoid can therefore be divided up into two times: a response time t
1
, the time that is necessary for the hook to be attracted against the pole plates, and the hold time t
2
, the time for holding the hook against the pole plates.
The weaving machines are becoming ever faster and the demand for faster hook selection devices in electronically controlled jacquard machines is therefore increasing. The response times of the solenoid can be shortened by applying a higher power supply voltage to the solenoids. The higher voltage causes a greater increase of current (dI/dt) and a greater current intensity (I) in the solenoid, so that the flux value whereby the hook will bend is reached faster. In other words the solenoid becomes faster. The higher voltage however also causes a hold current that is higher than necessary. The hold current is the current that the flux generates in order to exert an electromagnetic force on the hook that holds the hook on the pole plates with a minimum air gap. This measure therefore shortens the response time of the solenoid, but also produces a considerable increase in energy consumption. In view of the great number of selection devices in an electronically controlled jacquard device (going from a few thousand to 16 000), it will also be attempted to limit the energy consumption as much as possible.
A first measure that has been taken, according to the state-of-the-art, is to implement the energising in two phases: in a first phase an overenergising is applied of e.g. twice the hold voltage in order to obtain a short response time, and in a second phase a lower hold voltage is applied. The hold time of this hold voltage lasts much longer than the response time in the total selection time, so that this method already produces a considerable energy saving. The hold voltage is the electric voltage whereby the hold current flows through the solenoid.
This method of overenergising followed by a hold voltage requires a variable supply voltage that according to the state-of-the-art is effected with a switched power supply. This is called a voltage control. In view of the already mentioned great number of solenoids in a jacquard device, the power very quickly reaches several kW. At the relatively low supply voltage of 24-14 V that is used here the power supply has to be capable of furnishing hundreds of Amperes. These current intensities require electronic components that can withstand a high temperature stress and that are therefore relatively expensive and furthermore also sensitive to power failure due to overheating.
For the voltage control the supply voltage must be taken higher in order to compensate a few disadvantageous effects: namely variation of the electric resistance of the solenoid due to effect of the temperature and due to initial tolerances with the construction of the solenoid. This leads to higher hold currents than strictly necessary and therefore to energy wastage. Defective solenoids can only be detected on an idle machine, through which production losses sometimes arise with operating machines.
From the patent publication U.S. Pat. No. 4,511,945 a circuit for the energising of a solenoid is known, with which the electromagnetic force exerted by that solenoid can be regulated by controlling the current intensity in the solenoid, and not by controlling the electric voltage. The purpose of this circuit is to achieve a lower energy consumption of a solenoid in a fuel injector, and is therefore provided for the current control in one single solenoid. The circuit is furthermore also rather complex and comprises a large number of components, and is therefore also rather expensive.
In a hook selection device for a weaving machine generally thousands of solenoids are provided (e.g. 3,000 to 16,000 solenoids are standard numbers for jacquard machines). Since the known circuit is provided for energising one single solenoid, such a circuit would have to be provided per solenoid. Due to the large number of solenoids this would become too expensive, through which this circuit is not usable for a hook selection device for a weaving machine. Furthermore this circuit can also not be built sufficiently compact for this field of application.
SUMMARY OF THE INVENTION
A purpose of this invention is to provide a device with which solenoids of a hook selection device for a weaving machine can be energised, with which the electromagnetic force exerted by these solenoids can be regulated by a current control, and which due to its simplicity, compactness and low cost price is namely suitable for this field of application.
This aim is achieved by a device with the characteristics indicated in the first paragraph of this specification, of which per solenoid the regulating device comprises: a comparator provided for comparing the current intensity in the solenoid to a reference current intensity and a controllable current regulator, such as e.g. a chopper transistor, which is provided for regulating the current intensity in the solenoid in order to reach or approach this reference current intensity, while the regulating device comprises an electronic control circuit that is provided in order with several sole
Creighton Wray James
Dinkins Anthony
N.V. Michel Van de Wiele
Narasimhan Meera P.
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