SE507922C2 - Method and apparatus for feeding a dosed amount of sand - Google Patents

Abstract

For accomplishing feeding of a controlled or dosed quantity of sand to a water jet cutting tool, pressurized air with a controlled pressure is blown obliquely forwards in a channel (28) in a dosing insert (16) through a first bore (34) for creating a whirling injector action in the channel, to which sand is fed. At the same time surrounding air is sucked in through a second bore (36) to the channel in the vicinity of the first bore for increasing the sub-atmospheric pressure in the channel, decreasing the air speed and increasing the volume.

Description

50 20 9 507 922 v 3 horizontal duct in a dosing insert, to which duct sand is arranged to be supplied, is provided with an oblique going towards the duct, first bore, connected to a source of compressed air with a regulated pressure, and with a the ambient air connected, second bore adjacent to the first bore.

By using a device thus designed, a sand saving of up to about 40% can be achieved, at the same time as a clearly improved operational reliability in comparison with previously known devices can be noted.

To achieve a satisfactory, swirling injector effect in the channel, the first bore preferably extends substantially tangentially to the channel, which has a substantially circular cross-section, and forms an angle of 45-90 °, for example 66 °, with the longitudinal axis of the channel.

In order for the ambient air to be supplied in a manner correct for the intended effect, the second bore is substantially diametrically opposite the first bore, extends substantially tangentially to the duct and forms an angle of 45-90 °, for example 56 °, with the longitudinal axis of the duct.

To regulate the pressure of the compressed air supplied to the first bore, the device may suitably have an electrically controlled proportional valve and a manually adjustable throttle valve. The pressure of the compressed air can be in the range from 0 to 3-4 bar, the control voltage to the proportional valve of the needle valve type being 0-10 V.

The dosing insert can be arranged in a housing, the insert being provided with sealing O-rings. There may be means for indicating an increase in pressure inside the casing and thus a wear of the insert due to the sand in the channel.

The sand is preferably fed to the substantially horizontal channel in the dosing insert through a vertical w 922 input channel and out of there through a vertical output channel.

The sand can then be fed to the inlet channel from a lower storage thereof and to this lower storage via a valve controlled therein depending on the sand level therein from an upper storage. The sand can preferably be sucked into the upper storage by means of a negative pressure generated above the sand level in the storage, but more traditional feeding techniques are also conceivable.

The drawings The invention will be described in more detail in the following with reference to the accompanying drawings, in which Fig. 1 is a side view, mainly in section, of a sand dispenser according to the invention, Fig. 2 is a side view of a dosing insert included in the sand dispenser on a larger scale and with certain details omitted for clarity, Fig. 3 is a sectional view from above or along the line III-III in Fig. 4 of the insert shown in Fig. 2 in a housing, Fig. 4 is a cross-sectional view through the insert and the casing substantially along the line IV-IV in Figs. Fig. 5 is a simplified illustration of the pneumatic and electrical function of the device according to the invention and Fig. 6 is a diagram illustrating the output of sand from the device according to the invention as a function of an applied control voltage.

Description of a preferred embodiment A device schematically illustrated in Fig. 1 for discharging or dosing sand or a sand dispenser has, for example, a cylindrical upper housing 1 and a similarly, for example, a cylindrical lower housing 2.

The upper housing 1 is connected to a source (not shown) indicated by means of an arrow 3. for sand, The insertion of sand 507 9í2 W U 20 25 30 MTM 'I; one in the upper housing 2 is intended to be provided by means of negative pressure or vacuum at the upper part of the upper housing 1, as indicated by means of an arrow 4. To prevent sand from leaving the housing with the undercurrent current, a partition wall 5 with filter 6 arranged in the housing 1. The filters 6 can be cleaned by means of an annular blowing device 7 arranged over the filters 6 and connected to a compressed air bowl.

A capacitive sensor 8 is arranged in the upper housing 1 and is connected to an electric valve 9 for connecting the sand-sucking negative pressure in a manner indicated below. The blowing device 7 must of course be switched on in periods between sand intake.

The upper housing 1 can alternatively be kept properly filled with sand in a more conventional way than by suction, whereby the upper part of the device now described can be replaced with simpler means.

The upper housing 1 ends downwards with a conically tapered insert part 10. The housing 1 and the insert part 10 can together be said to form an upper storage for sand.

The insert part 10 has a lower outlet opening, which is normally kept closed by means of a conical valve body 11.

This valve body 11 is connected by means of a valve rod 12 to a pneumatic cylinder 13 for opening the valve 11.

A capacitive sensor 14 in the wall of the lower housing 2 is connected to the cylinder 13 for its control in a manner indicated below.

The lower housing 2 ends downwards with a funnel 15. The housing 2 and the funnel 15 can together be said to form a lower storage for sand.

When the sand in the lower supply 2, 15 has dropped below a certain level, the sensor 14 gives a signal to the cylinder 13 for opening the valve 11. When the correct level is reached, the sensor 14 gives a signal to the cylinder 13 for closing the valve 11. When the cylinder 13 closes the valve 11, a signal is given to the electric valve 9 to take in more sand to the upper supply 1, 10. The valve 9 is open until the sensor 8 gives a signal that the correct sand level has been reached and closes the valve 9.

The funnel 15 leads the sand down to the very core of the device, namely a dosing insert 16 described in more detail below, placed in a housing 17 and provided with sealing O-rings (not shown).

This housing 17 is mounted on a base plate 18, from which a cover 19 extends up to the insert part 10. An angle bracket 20 is mounted between the housing 17 and the lower housing 2. The cover 19 is provided with a lid 21, through which, among other things, the dosing insert 16 can be accessed.

Attached to the angle bracket is an electrically controlled proportional valve 22 described below. In the housing 19 is attached a manually adjustable throttle valve 23, at least one manometer 24 all described below. will now be described with reference to Figs. 2-4 and to some extent also to Figs. 1 and 5. and at least one control lamp 25, The dosing insert 16 (and its housing 17) It appears from Fig. 1 that the funnel 15 extends into a slightly conical channel 26 in the housing 17; In line with the channel 26, a vertical input channel 27 in dosage, cf. also Fig. 4, is the ring insert 16, which channel leads to a longitudinal or horizontal channel 28, which in turn leads to a transverse output channel 29.

This outlet channel 29 is provided with an end widening 29 ', 18' in the bottom plate 18 corresponding to an opening 30 in the housing 17 and an opening (Fig. 1). The end extension 29 'is provided with a seal 31, and a conduit (not shown) is intended to be sealed in the openings 30 and 18' against the seal 31. This conduit extends to a tool (not shown), preferably a screen nozzle, in which a high-pressure water - a jet is mixed with the sand coming from the dispenser according to the invention according to the invention in order to enable cutting into different pieces of material.

At its end adjacent to the inlet channel 27, the longitudinal channel 28 is provided with a breath plug 32, so that a closed channel 27, 28, 29 for sand is formed through the dosing insert 16. The longitudinal channel preferably has a circular cross-section and can, for example, have a diameter of 12 mm.

The dosing insert 16 is provided in its surface with a number, for example three, circumferential bars (not shown) for O-rings for sealing against the housing 17 and a keyway 16 'for position-fixing interaction with a screw 33 in the housing 17 (Fig. 1).

A two-plane, first bore 34 extending, as shown in Figs. 3 and 4 but not in Fig. 2 for the sake of clarity, from the surface of the insert 16 into the longitudinal channel 28 downstream of the entrance channel 27. an axial bore 35 extends to the end surface of the insert 16. The bores 34 and 35 constitute a supply of compressed air to the longitudinal channel 28 in a manner described below and may, for example, have a diameter of 3 mm.

As shown in Fig. 4, the bore 34 extends substantially tangentially to the channel 28 and may, for example, form an angle of 8 ° with the horizontal. Seen in Fig. 3, the bore 34 extends obliquely inwards or directed downstream towards the channel 28. The angle with the axis of the insert 16 can, for example, be 66 °. The purpose of this oblique blowing of compressed air through the bore 34 is to create a swirling injector effect in the longitudinal channel 28, so that a regulated amount of sand is sucked in from the inlet channel 27.

However, the negative pressure thus created can give rise to a certain problem, which can be remedied in the manner indicated below.

In principle diametrically opposite the first bore 34 is, as shown in Figs. 3 and 4 but not Fig. 2, arranged an oblique, second bore 36 from the surface of the insert 16 to the channel 28, and an axial bore 37 connects this bore to the end surface of the insert. The second bore 36 leads, as shown in Fig. 4, tangentially to the duct 28 parallel to the horizontal and forms, as shown in Fig. 3, an angle of, for example, 56 ° with the axial direction of the insert 16, i.e. is slightly more inclined than the compressed air bore 34.

The second bore 36, 37 is connected to the ambient air, and its purpose is to reduce the overpressure in the duct 28 by sucking in supply air, lower the air velocity and increase the volume of sand, whereby the otherwise strong wear on the insert 16 from the sand in channel 28 is reduced.

A tubular insert (not shown) with an inner diameter of, for example, 3 mm can be arranged in the second bore 36. This insert may be inserted slightly into the channel 28 to achieve improved flow conditions in the channel for the purposes of the invention.

With reference to Fig. 5 but also the other figures, the function of the sand dispenser will now be described. Fig. 5 shows the dosing insert 16 with its housing 17 as a reduction of Fig. 3. As indicated by an arrow 40, the bore 37 is connected to the ambient air, while the bore 35 is connected to an air supply system as below.

Through a line 41, compressed air is supplied to the device with a pressure of, for example, 6 bar. By means of a manually set regulator 42, this pressure is reduced to a stable pressure of 3-4 bar, which is supplied to the proportional valve 22 through a line 43 and which is shown on the manometer 24. This proportional valve 22, which is a needle valve , is taken with a control voltage of 0-10 V. The pressure of the air supplied from the valve through a line 44 varies in relation to the control voltage and is shown on the manometer 24. A manual calibration of the pressure can also be achieved with 507 9ê2 10 15 20 25 B) Llu ri »= by means of the throttle valve 23, before the compressed air is fed into the bore 35 of the insert 16 through a line 45.

By means of the control voltage to the proportional valve 22, the air pressure in the bore 34 in the dosing insert and thereby also the inflow of air in the supply air bore 36 is thus controlled. further transport to the cutting nozzle (not shown), where the sand is mixed with water to a cutting liquid.

To ensure that the screen nozzle has sand directly from the start, the dosing device according to the invention can be started a few milliseconds before the nozzle with the aid of the common computer which can control the plant.

Due to the fine control that can be achieved with the aid of the device according to the invention, an optimal utilization of the sand is obtained without any spillage.

The result of practical experiments with a device according to the invention is shown graphically in Fig. 6. By varying the control voltage from 3.0 to 6.5 V, a surprisingly rectilinear discharge of sand could be achieved through the dosing insert 16 from practically 0 to 600 g / min. The solid line shows the results of the practical experiments, while the dashed line is a straight reference line.

The wear of the sand inside the dosing insert 16 is considerable. A pressure switch 46 of the microswitch type can thus be connected via a filter 47 to an opening in the wall of the housing 17, as indicated in Fig. 5. During pressure increase, which indicates wall breakage, the control voltage to the proportional valve 22 is broken, 25 lights up. At the same time, the water jet to a connected cutting tool can be switched off.

It is thus obvious that the dosing insert 16 needs to be replaced time after time. This exchange can take place without much difficulty through the cover 21 shown in Fig. 1. ¿so? 922 1 v}.

The device according to the invention has been described in its use together with a water jet tool, but other areas of use are also conceivable. The use of a cutting tool, in which the sand is mixed with high-pressure air instead of water, is particularly close at hand.

In general, the technique developed by the invention can be used in feeding or dosing all kinds of particulate materials, such as in the food industry, the pharmaceutical industry and the paint industry.

Claims (10)

507 92l2 W U 20 25 30 | ('?; 10 PATENT REQUIREMENTS When feeding a regulated or dosed amount of sand or similar material, for example to a water jet cutting tool, characterized in that compressed air with a regulated pressure is blown obliquely forward in (28) through a first bore (34) a substantially horizontal channel (16) swirling injector action in the channel, in a dosing insert for creating a to which sand is supplied upstream of the bore, and that ambient air is sucked in through a second bore (36) to the channel adjacent to the first bore to reduce the overpressure in the duct, lower the air velocity and increase the sand volume. Device for carrying out the method according to claim 1, for producing a regulated or dosed amount of sand, characterized in that a substantially horizontal (28) (16) for supplying sand and downstream thereof with the first bore (34), for compressed air with a sonal channel in a dosing insert is provided with (27) an oblique going towards the channel, (22, 23) and with a pressure regulated with the surrounding air means connected to a source, connected, second bore (36) in connection with the first bore. k n n e t e c k n a d (34) substantially tangentially to the channel (28), which has a main Device according to claim 2, wherein the first bore extends substantially circular cross-section, and forms an angle of 45-90 °, for example 66 °, with the longitudinal axis of the channel and that the second bore (36) is substantially diametrically opposite the first bore, extends mainly tangentially to the channel and forms an angle of 45-90 °, for example 56 °, with the longitudinal axis of the channel. Device according to Claim 2, characterized by an electrically controlled proportional valve (22) and a male, 507 922 (23) of the throttle valve which can be adjusted to the first bore (34) for regulating the compressed air. . Device according to Claim 4, characterized in that the pressure of the compressed air supplied to the bore (34) is in the range from 0 to 3-4 bar. Device according to claim 4, characterized in that the control voltage to the proportional valve (22) of the needle valve type is 0-10 V. Device according to claim 2, characterized in that the dosing insert (16) is arranged in a housing (17) and is provided with sealing O-rings and that there are means (46) for indicating a pressure increase inside the housing and thus a wear of the insert due to the sand in (28). Device according to claim 2, characterized in that the channel is fed in that the sand is fed into the substantially horizontal channel (28) in the dosing insert (16) through a vertical inlet channel (27) and out therefrom through a vertical outlet (27). 29). Device according to claim 8, characterized in a passage channel, in that the sand is fed to the entrance channel (27) from a lower store (2, 15) thereof and to this lower store via a valve (11) controlled therein depending on the sand level from 10. ). Device according to claim 9, characterized in that an upper store (1, in that the sand is sucked into the upper store (1, 10) by means of a negative pressure generated above the sand level in the store.