WO1982000516A1 - Device for metering liquids - Google Patents

Abstract

The liquid-metering device, which may be fasten on a container (1), comprises a valve unit (10) with a T-shaped body (11), whose arms which are aligned with the valves controlled by springs are connected to an upstream circuit (3) and to a distribution conduit (7) and whose shank is made of a metering unit (50). The metering unit (50) comprises a metering chamber (51) with a metering piston (52) connected by its bottom (15) to the valves. The metering piston (52) is kept in the out position at the end of the stroke by a spring (83); it is movable in a guide (53) one extremity of which is screwed on the bottom (14), the other extremity bearing a push-rod (80, 110) for the metering piston (52). The stroke of the metering piston is determined by washers (87, 90, 100, 105) provided on the guide (53) or by elements (112, 113, 114) engaging the guide (83) and the push-rod (110).

Description

 Dosing device for liquids

Technical field

The invention relates to a metering device for connection to a liquid container, consisting of a valve device with one-way ball valves, at least one of which is held resiliently in the closed position and one of which is an inlet valve which is connected on the inlet side to a riser pipe leading into the liquid container, and the other forms an outlet valve which is connected on the output side to a dispensing device for the metered liquid, and from a metering chamber connected between the inlet valve and the outlet valve to the valve device with a metering piston which can be displaced within the metering chamber for receiving and dispensing precisely measured and adjustable amounts of liquid.

Underlying state of the art

A known metering device of this type is placed on a bottle and forms a self-contained one

Component with an externally accessible adjustment device with a scale for the dosing piston. In a lower part that is not easily accessible from the outside the valve device, wherein the inlet valve in the extension of the riser and the outlet valve, which is connected to a discharge line attached to the lower part, are arranged transversely thereto.

The known metering device does not work precisely enough so that even small amounts of liquid, e.g. in the range below 100 ul, to be able to dose with the desired accuracy. In particular, there is a risk that air bubbles sucked in through the riser will get past the outlet valve into the metering chamber and collect in the metering chamber without being observable. is; An air cushion between the dosing piston and the liquid surface significantly affects the accuracy of the dosing of small amounts of liquid.

Accordingly, the object of the invention is to provide a metering device of the type mentioned, which also allows the metering of small amounts of liquid with sufficient accuracy.

Disclosure of the invention

According to the invention, this object is achieved in that a valve unit forming the valve device with a T-shaped valve housing, in the arms of which the inlet valve and the outlet valve are inserted in alignment with one another from the ends, and a metering unit releasably connected thereto, which are provided in the trunk of the valve housing formed metering chamber, which is delimited at one end by a connecting part with separate connecting lines to the outlet of the inlet valve and to the inlet of the outlet valve and at the other end by a stop ring of a guide releasably fastened to the stem of the valve housing, and a metering piston biased in the suction direction with a Hubflansch has whose stroke through the stop ring and an adjustable on the guide stop body is determined, and that the metering piston is arranged at a predetermined minimum distance from the connecting part when the lifting flange against the stop ring.

In the metering device according to the invention, the valve unit and the metering unit are arranged transversely to one another, so that the metering piston is no longer at the highest point of the metering device and no air bubbles can collect under the metering piston. In addition, the construction of the dosing device from separate valve and dosing units has the advantage that both units can e.g. for maintenance and repair purposes are easily accessible and their function can be easily monitored. Furthermore, the metering unit arranged transversely to the valve unit allows the metering device to be held and actuated only by hand, regardless of a fixed base.

Advantageous embodiments of the metering device according to the invention are characterized in the subordinate claims.

The valve housing has opposite, outwardly opening, pot-shaped receptacles for holding bodies with central inner channels for the valve balls, and the

Holding bodies are each provided with a recess opposite the valve seats, in which the valve balls are resiliently biased in the closing direction. Thanks to the modular

Construction, all components of the valve unit are easily accessible. In particular, the valve balls of both valves are resiliently biased against the valve seats, so that the safe closure of the inlet valve is ensured even when the metering device is not in the vertical position.

Advantageously, a plurality of spring bars projecting from the base of the concavity against the valve ball, tapering towards the latter and resting on the surface thereof, and at least between two spring bars are a limitation provided that can be formed in one piece with the holding body.

The valve unit in the metering device according to the invention is expediently made of plastic and the plastic is from the group: polyolefins; perfluorinated polyolefins, chlorofluorinated polyolefins selected. This eliminates corrosion problems. The valve seat can consist of an elastic plastic and the valve ball can be made of an abrasion-resistant, non-electrostatically chargeable material. This material can be ruby, sapphire, ceramic or even a corrosion-resistant metal, to which the suspended matter contained in the liquid to be dosed is not retained when it flows through the valve. This ensures that the valve closes securely.

In the metering device according to the invention, the connecting part has a mouth part which extends coaxially into the trunk of the T-shaped valve housing and whose outer diameter corresponds to the inner diameter of the stop ring, and the metering chamber is a glass tube whose width corresponds to the inner diameter of the stop ring and one end of which sealingly abuts the mouth part and the other end of the stop ring. The connecting part can have a viewing window in the region of the mouth part. This creates a dosing chamber that can be constantly monitored for the absence of air from the dosing chamber when the dosing device is being filled and during operation.

Advantageously, in the metering device according to the invention, a cup-shaped, axially adjustable stop body is inserted into a second end of the tubular body forming the guide, the bottom of the recess facing the stop ring facing out axially to the glass tube and to the stop ring Directed breakthrough and the open end of which is provided with an edge part, and between the ring flange of the guide and the edge part is arranged a cross-over the second end of the guide, with one end face of the ring flange. This not only creates an adjustable stroke limitation for the dosing piston by inserting the stop body more or less deeply into the guide, but it also makes it possible to carry out large strokes with the dosing piston. This facilitates the first, air-free filling of the dosing device with the liquid to be dosed and the reliable ventilation during operation, but is advantageous for flushing, for example when changing the liquids.

Brief description of the drawings

Exemplary embodiments of the invention are shown in the figures and are explained and described in detail below using the reference symbols. Show it

Figure 1 is a partially sectioned overall view of the metering device according to the invention.

2a shows a central longitudinal section through the inlet valve;

2b shows a central longitudinal section through the outlet valve, in each case in the closed position, in the metering device according to FIG. 1;

3 shows a central longitudinal section on an enlarged scale through the metering unit in the metering device according to FIG. 1;

4 shows a plan view of an annular disk in the metering unit according to FIG. 3; 5 shows a central longitudinal section through part of a second exemplary embodiment of the metering unit;

6 shows a central longitudinal section through part of a third exemplary embodiment of the metering unit;

Fig. 7 shows a detailed view of the clamping sleeve and the washers in the metering unit

Figure 6;

8 shows a central longitudinal section through part of a fourth exemplary embodiment of the metering unit; and

9 shows a plan view of the circumference of the stop body in the metering unit according to FIG. 8.

Best way to carry out the invention

The overall view of the metering device in FIG. 1 shows a liquid container in the form of a bottle 1, on the mouth of which an attachment in the form of a double sleeve 2 is placed, by means of which the bottle opening is closed and the metering device is held on the bottle 1. The metering device consists of a valve unit 10 and a metering unit 50. The valve unit 10 is connected on the input side to a riser 3, which carries a filter housing 4 with a teflon screen and a steel core 5 at its free end. The riser 3 is passed through a grommet 6 of the filter housing 4. On the output side, the valve unit 10 is connected to an output line 7 which is fastened to the bottle 1 by a holder 8. The valve unit 10 consists of a generally T-shaped valve housing 1 1 made of Teflon or a chlorofluorinated polyolefin. An inlet valve 1 2 is placed in one arm and an outlet valve 1 3 in the other arm of the valve housing 1 1. Between the inlet valve 12 and the outlet valve 13 there is a connecting part 1 4, which runs partially transversely thereto, which forms the trunk of the T-shaped valve housing 1 1 and to which the metering unit 50 is connected.

In particular, the inlet valve 12 consists of a cylindrical, pot-shaped receptacle 15, which is screwed into the internal thread of the free end of the double sleeve 2 with an external thread. In the double sleeve 2, a valve seat body 16 is inserted, which abuts an inner annular shoulder 17 of the double sleeve 2 and has a central bore 18. At the end facing the bottle 1, the valve seat body 16 carries a clamp 19 into which the riser 3 is inserted. On the side facing away from the grommet 19, the valve seat body 16 carries a valve seat 20 made of an elastic perfluorinated polyolefin, which can also consist of a polyolefin. The valve seat 20 is supported by a valve ball 21 made of ruby, which can also consist of another abrasion-resistant material that cannot be electrostatically charged, such as sapphire, ceramic or a corrosion-resistant metal. In the receptacle 15, a holding body 22 is inserted flush, which consists of Teflon, but can also consist of chlorofluorinated polyolefin. The structure of the holding body 22 can best be seen in FIG. 2a: The holding body 22 is then provided with a recess 23 opposite the valve seat 20, from the bottom of which a central inner channel 24 extends to the other end of the holding body 22. From the bottom of the recess 23, three spring rods 25, offset by 120 °, run in the direction of the valve ball 21 and rest on their surface under elastic deformation with a tapered end. Between the spring bars 25 there are limit stops 26 which end at a predetermined distance from the valve ball 21. Only one of the spring bars 25 and the limit stops 26 can be seen in the illustration in FIG. 2a. The distance of the limit stops 26 from the valve ball 21 is selected so that when the valve ball 21 is in contact with the limit stops 26, the inlet valve 12 is fully open and the deformation of the spring rods 25 still remains in the range of the elastic deformation. The spring bars 25 and the limit stop flange 26 are designed and arranged with respect to one another in such a way that they do not hinder the flow from the valve seat 20 to the inner channel 24.

In particular, the outlet valve 13 consists of a cylindrical, cup-shaped receptacle 27, on the bottom of which a valve seat 28 is formed. The valve seat 28 is one

Valve ball 29 on. The valve seat 28 and the valve ball 29 are made of the same material as the corresponding parts of the inlet valve 12. A holding body 30 is inserted flush into the receptacle 27 and is made of the same material as the holding body 22. The structure of the holding body 30 is best seen in FIG. 2b: Thereafter, the holding body 30 is provided with a recess 31 opposite the valve seat 28, from the bottom of which a central inner channel 32 extends to the other end of the holding body 30. From the bottom of the recess 31, three spring rods 33, which are offset by 120 ° from one another, run in the direction of the valve ball 29 and rest on their surface with elastic deformation with a tapered end. Limiting stops 34 are located between the spring bars 33 and end at a predetermined distance from the valve ball 29. Only one of the spring bars 33 and the limit stops 34 can be seen in the illustration in FIG. 2b. The distance of the

Limit stops 34 of the valve ball 29 is selected so that when the valve ball 29 abuts the limiter stop 34 the exhaust valve 13 is fully open and the deformation of the spring rods 33 still remains in the range of the elastic deformation. The spring bars 33 and the limit stops 34 are designed and arranged to each other that they do not hinder the flow from the valve seat 28 to the inner channel 32. At the end facing away from the recess 31, the holding body 30 carries a tapered axial shoulder 35 with the formation of an annular shoulder 36. The holding body 30 is in the valve unit by a union nut 37 which engages on the annular shoulder 36 and is guided on an external thread of the receptacle 27 10 supported. Extending through the union nut 37 is the axial extension 35, in the end face of which the inner channel 32 opens out with an enlarged end, to which the delivery line is connected by a plug-in connection which is secured by a fuse 38 which overlaps the axial extension 35 from the outside.

The middle part and the trunk of the T-shaped valve housing are formed by a connecting part 14, the middle part of which contains a connecting line 39 starting from the inlet valve 12 and a connecting line 40 starting from the outlet valve 13, cf. in particular Figure 3.

The connecting part 14 essentially forms a hollow

Pipe section 41, at one end of which a coaxial opening piece 42 is formed, into which the connecting lines 39, 40 open, and at the other end an external thread is provided for connection to the metering unit 50. The pipe section 41 is provided on one side with a viewing window 43 which is formed in the region of the mouth part 42. The

Dosing unit is one in the trunk of the T-shaped

Valve housing 11 formed metering chamber 51 and a

Dosing piston 52 formed in one on the pipe section

41 from the end screwed on guide 53 is guided adjustable, cf. Figure 3. To achieve more reliable Venting is the mouth for the outlet-side connecting line 40 diametrically above the mouth for the inlet-side connecting line 39th

The metering chamber 51 is axially delimited by a glass tube 55 made of device glass, the inside diameter of which corresponds to the outside diameter of the mouth part 42 and which is pushed over the mouth part 42 and abuts the connecting part 14 with the interposition of an annular sealing disk 56. The sealing washer 56 is made of a perfluorinated polyolefin which is suitable for sealing glass surfaces and is deformable under mechanical pressure. At the other end, the glass tube 55 protrudes somewhat beyond the connection part 14 and lies with its end face against a stop ring 57 arranged in the guide 53, the inside diameter of which is adapted to the inside diameter of the glass tube 55.

The metering piston 52 consists of a divided piston rod 60. A first part of the piston rod 60 carries at its inner end in the glass tube 55 a piston head 61. The piston head 61 forms in a known manner a tapered end, the steps carrying sealing rings, and is provided with a non-elastic cover which abuts the inner wall of the glass tube 55 with circumferentially extending projections 62. This first part is connected by a screw head 63 to a second, reinforced part of the piston rod 60, and at the transition point between the two parts there is a lifting flange 64 with a centering flange 65 facing the piston head 61 and having a larger diameter than the piston head 61 which protrudes into the stop ring 57. The second part of the piston rod 60 carries an operating button 66 at its outer, again thickened end, which protrudes from the guide 53, and at the transition point to the thickened one An annular shoulder 67 is formed at the end, which serves as an abutment for a spring in a manner to be described.

The guide 53 forms a tubular body open on both sides, the first end of which is screwed onto the connecting part 14 of the valve housing 11. An annular shoulder 70 is formed on the inside at the connection point between the first and second ends of the tubular body. The stop ring 57 bil det on the side facing away from the glass tube 55 a raised edge 71 and a central recess 72, the diameter of which is sufficient to accommodate the lifting flange 64 on the piston rod 60. The stop ring 57 has an opening 73 which tapers slightly in the direction of the glass tube 55 and to which the shape of the centering flange 65 connected to the lifting flange 64 is adapted. The guide 53 is screwed with its first end so far onto the connecting part 14 that the stop ring 57 bears on the one hand against the glass tube 55 and on the other hand with its raised edge 71 the ring shoulder 70. On the outside, the guide 53 carries an annular flange 74, which is provided with a recess 75 on the side facing away from the valve unit 10.

The stop ring 57 thus forms a fixed stop for the stroke of the metering piston 52. The variable stop for the stroke adjustment is connected to the second end of the guide 53 and is described in detail below. A generally cup-shaped stop body 80 is screwed into the internal thread of the second end of the tubular body. The stop body 80 has an inner width which is adapted to the diameter of the thickened end of the metering piston 52, so that the metering piston 52 is guided therein with its thickened end. Inwardly, the width of the stop body 80 decreases near its bottom 81; the bottom 81 is with a through break 82 provided, the diameter of which corresponds to that of the reinforced second part of the metering piston 52, which is also performed in this area. A spring 83 is supported on the base 81, which engages the annular shoulder 67 of the piston rod 60 and prestresses the metering piston 52 in such a way that the lifting flange 64 is held in contact with the base 81. The stop body 80 is provided with an edge part 84 at its open end. Between the edge part 84 and the ring flange 74 of the guide 53, a clamping sleeve 85 engages over the second end of the guide 53; it rests with its end face on the ring flange 74 and carries at the other end a threaded part 86 with which it is guided on the external thread of the stop body 80. The clamping sleeve 85 is screwed onto the stop body 80 up to an end stop (not shown). In the recess 75 of the annular flange 74 there are stroke-limiting means in the form of an annular disk 87 with a recess 88 (FIG. 4) extending from the circumference thereof and an indicator disk 89 arranged underneath, which bears the quantity information which is made visible by the recess 88 when the annular disk 87 is rotated become. The clamping sleeve 85 bears against the annular disk 87 which is respectively introduced into the recess 75.

The dosing device shown in FIG. 3 is shown in its starting position before a dosing process. An annular disk 87 corresponding to the desired metering quantity is introduced into the recess 75; the stop body 80 is screwed into the second end of the guide 53 with the clamping sleeve 85 screwed onto its thread up to the end stop until the clamping sleeve 85 rests on the annular disk 87. The stroke of the lifting flange 64 of the metering piston 52 in the recess 72 of the stop ring 71 between the bottom 81 of the stop body 80 and the base of the recess 72 is then given by the thickness of the annular disk 87. This stroke distance corresponds to one out of the glass tube 55 displaced amount of liquid, which is indicated by the recess 88 on the annular disc 87. When the metering piston 52 is actuated against the force of the spring 83, the outlet valve 13 is opened and the set amount of liquid is conveyed through the discharge line 7. At the end of the stroke, the front end of the piston head 61 is at a minimum distance from the connecting part 14, which is predetermined by the depth of the recess 72 in the stop ring 57. This ensures that air bubbles which have entered the liquid column in the region of the valve unit 10 do not collect on the piston head 61 , but are always conveyed through this part of the glass tube 55 and the device 40 to the outlet valve 13. At the end of the metering process, the metering piston 52 returns to the starting position shown in FIG. 3 under the action of the spring 83, the inlet valve 12 opening against the action of the spring bars 25 and the outlet valve 13 under the action of the spring bars 33 (and the pressure difference ) remains closed. The viewing window 43 permits continuous observation and control of the metering process.

For venting or flushing the metering device after a change of liquid, the stroke of the metering piston 52 can be slightly increased in that the stop body 80 is moved outwards in the second end of the guide 53 while the clamping sleeve 85 is held in place. This adjustment can be made after venting or

Undo flushing without further ado, since the end stop on the external thread of the stop body 80 ensures a mutual adjustment between the stop body 80 and the clamping sleeve 85 that can be reproduced with high accuracy.

5 shows a second exemplary embodiment of the metering unit 50. Corresponding parts are provided with the same reference symbols. You can see that in the picture Glass tube 55, the metering piston 52 with the piston head 61, the lifting flange 64 and the operating head 66, and the guide 53 with the stop ring 57, the ring flange 74, the stop body 80 and the clamping sleeve 85. In this embodiment, however, the stroke limiting means are not on the Ring flange 74, but arranged between the edge part 84 of the stop body 80 and the threaded part 86 of the clamping sleeve 85. The stroke limiting means are formed here by not completely closed annular disks 90, which can be easily brought over the stop body 80 and are provided on their peripheral surface with an indication of the amount of liquid conveyed. The washers 90 are held between opposite recesses 91 and 92 in the edge part 84 or threaded part 86.

A third embodiment of the dosing unit 50 is shown in FIGS. 6 and 7. Corresponding parts are provided with the same reference numerals. The figure shows the glass tube 55, the metering piston 52 with the piston head 61, the lifting flange 64 and the operating head 66, and the guide 53 with the stop ring 57, the ring flange 74, the stop body 80 and the clamping sleeve 85 the stroke limiting means, however, are not arranged on the ring flange 74, but between the edge part 84 of the stop body 80 and the threaded part 86 of the clamping sleeve 85. The stroke limiting means are formed here by not completely closed annular disks 100, which can be easily brought over the stop body 80 and carry a radial projection 101 with a quantity. A plurality of such annular disks 100 can then be arranged offset at an angle to one another, so that the total amount of liquid delivered is always recognizable. The annular discs 100 are provided with holes 102 distributed over their surface, with which they are pushed onto pins 103 protruding from the end face of the threaded part 86. For larger strokes, ring washers 105 can be used an engagement groove 106 can be used on one side, in which the pins 103 then engage (Figure 7). The edge part 84 of the stop body 80 is provided with a corresponding groove 107.

A fourth exemplary embodiment of the dosing unit 50 is shown in FIGS. 8 and 9. Corresponding parts are provided with the same reference numerals. One can see in the figure the glass tube 55, the metering piston 52 with the piston head 61, the lifting flange 64 and the operating button 66, and the guide 53 with the stop ring 67 and the ring flange 74. In this embodiment, however, the stop body, the clamping sleeve and the second end of the guide 53 is not screwed together, but the second end of the guide 53 and the stop body 110 are provided with interlocking engagement elements, both of which are locked together in specific, predetermined axial pitches, each of which corresponds to a specific stroke of the metering piston 52. For this purpose, the stop body 110 above the base 111 has three slot combinations consisting of an axial slot 112 and transversely therefrom at certain axial intervals circumferential slots 113 which are offset from one another by an angle of 120 and one of which is shown in a top view in FIG. 9. The second end of the guide 53 carries on its inner wall three pins 114 which are offset from one another by an angle of 120 and which are in engagement with the slot combinations. The stop body 110 can only be axially adjusted relative to the second end of the guide 53 if it assumes such an angular position that the pins 114 are located in the axial slots 112. The clamping sleeve 115 is guided on an external thread of the second end of the guide 53; it has quantities on its circumferential surface; these are made visible by recesses 113 in a guide sleeve 117 which extends from an edge part 116 of the stop body 110 and overlaps the clamping sleeve 115.

Claims

Claims

1. Dosing device for connection to a liquid container, consisting of a valve device with one-way ball valves, at least one of which is held resiliently in the closed position and one of which is an inlet valve which is connected on the inlet side to a riser pipe leading into the liquid container, and the other of which is an outlet valve forms, which is connected on the output side to a dispensing device for the metered liquid, and from a metering chamber connected between the inlet valve and the outlet valve to the valve device with a metering piston which can be displaced ver within the metering chamber for receiving and dispensing precisely measured and adjustable amounts of liquid,

characterized in that a valve unit (10) forming the valve device with a T-shaped valve housing (11), in the arms of which the inlet valve (12) and the outlet valve (13) are inserted flush with one another from the ends, and a detachably connected thereto Dosing unit (50) are provided, which in the trunk of the valve housing (11) formed dosing chamber (51) which at one end by a connecting part (14) with separate connecting lines (39, 40) to the outlet of the inlet valve (12) and Entrance of the outlet valve (13) and at the other end by a stop ring (57) of a guide (53) detachably fastened to the stem of the valve housing (11), and having a metering piston (52) pretensioned in the suction direction with a lifting flange (64), its stroke through the stop ring (57) and an adjustable stop body on the guide (80, 110) is determined, and that the metering piston (52) is arranged at a predetermined minimum distance from the connecting part (14) when the lifting flange (64) bears against the stop ring (57).

2. Dosing device according to claim 1, characterized in that the valve housing (11) opposite, outwardly opening, pot-shaped receptacles (15,27) for holding body (22,30) with central inner channels (24,32) for the valve balls ( 21, 29) and that the holding bodies (22, 30) are each provided with a recess (23, 31) opposite the valve seats (20, 28), in which the valve balls (21, 29) are resiliently biased in the closing direction.

3. Dosing device according to claim 2, characterized in that a plurality of projecting from the bottom of the recess (23, 31) against the valve ball (21, 29), tapering towards the latter and the surface of which rests on spring bars (25, 33) and at least between two spring bars (25, 33) a limit stop (26, 34) are provided.

4. Dosing device according to claim 3, characterized in that the spring bars (25,33) are offset from one another by an angle of 120 °.

5. Dosing device according to claim 3 or 4, characterized in that the spring bars (25,33) and the limit stops (26,34) are formed in one piece with the holding body (22,30).

6. Dosing device according to one of claims 2 to 5, characterized in that the holding body (22) of the inlet valve (12) fills the receptacle (15) flush and its inner channel with the associated connection Line (39) of the connecting part (14) is aligned so that the valve seat (20) of the inlet valve (12) on a valve seat body (16) with a central, in the valve seat (16) opening (18) is arranged, which at the Valve seat (20) facing away from the riser (3) can be connected, and that the receptacle (15) is set up for connection to an attachment at the mouth of the liquid container.

7. Dosing device according to claim 6, characterized in that the riser (3) ends within the liquid container in a filter housing (4) provided with a weight.

8. Dosing device according to one of claims 2 to 5, characterized in that the valve seat (28) of the outlet valve (13) is arranged at the base of the receptacle (27), that the holding body (30) at the end facing away from the valve seat (28) has a tapered axial approach (35) and through this

Approach inner channel (32) can be connected to the dispenser and that the holding body (30) by a union nut (37) which is guided on the receptacle (27) and engages the annular shoulder (36) formed by the approach (35), is supported.

9. Dosing device according to claim 8, characterized in that a the axial approach (35) overlapping fuse (38) for a with the inner channel (32) connected discharge line (7) is provided.

10. Dosing device according to one of claims 2 to 9, characterized in that the valve unit (10) is made of plastic and that the plastic from the group: polyolefins; perfluoriertε polyolefins, chlorofluorinated polyolefins is selected.

11. Dosing device according to claim 10, characterized in that the valve seat (20, 28) consists of an elastic plastic and the valve ball (21, 29) consists of an abrasion-resistant, non-electrostatically chargeable material.

12. Dosing device according to one of the preceding claims, characterized in that the guide (53) forms a tubular body open at both ends and has an inner annular shoulder (70) and an annular flange (74) between its ends.

13. Dosing device according to claim 12, characterized in that a stop ring (57) is inserted in a first end of the tubular body, which is provided on one side with a recess (72) and with a raised edge (71) of the annular shoulder (70) abuts, and that the first end of the tubular body is releasably attached to the connecting part (14) of the valve housing (11).

14. Dosing device according to one of claims 2 to 11 and claim 12 or 13, characterized in that the connecting part (14) has a mouth part (42) which extends coaxially into the stem of the T-shaped valve housing (11) and its outer diameter corresponds to the inside diameter of the stop ring (57) and that the metering chamber (51) is a glass tube (55), the width of which corresponds to the inside diameter of the stop ring (57) and one end sealing the mouth part (42) and the other end of the stop ring (57 ) is present.

15. Dosing device according to claim 14, characterized in that the connecting part (14) in the region of the mouth part (42) has a viewing window (43).

16. Dosing device according to one of claims 12 to

14, characterized in that in a second end of the tubular body forming the guide (53) a cup-shaped, axially adjustable with respect to the tubular body stop body (80, 110) is inserted, the

Recess (72) in the bottom ring (57) facing the stop ring (57) with an opening (82) oriented axially to the glass tube (55) and the stop ring (57) and the open end of which is provided with an edge part (84, 116), and that between the ring flange (74) of the guide (53) and the edge part (84, 116) there is arranged a clamping sleeve (85, 115) which overlaps the second end of the guide (53) and has one end face against the ring flange (74).

17. Dosing device according to claim 16, characterized in that the stop body (80) is guided in a thread of the second end of the guide (53), that the clamping sleeve (35) abuts an end stop on the impact body (80) and that the stop body (80) and the clamping sleeve (85) guided thereon are axially adjustable relative to one another.

18. Dosing device according to claim 16, characterized in that the stop body (110) and the second

End of the guide (53) are provided with intermeshing engagement elements which, in a first engagement position, permit the stop body (110) to be axially displaced with respect to the guide (53) and in a second engagement position the stop body (110) is axially opposite the guide (53). lock, and that the clamping sleeve (115) is guided on the outside at the second end of the guide (53).

19. Metering device according to one of claims 16 to 18, characterized in that the metering piston (52) passing through the stop body (80, 110) has a piston head (61) sealingly sliding in the glass tube (55) and an operating button (66) outside the guide (53) ) supports that the lifting flange (64) is arranged in the space delimited by the recess (72) in the stop ring (57) and the bottom (81, 111) of the stop body (80, 110) and that the metering piston (52) is arranged by a on the bottom (81, 111 ) of the stop body

(80, 110) supported spring (83) is biased into a position in which the lifting flange (64) is on the ground

(81,111) is present.

20. Dosing device according to claim 19, characterized in that the lifting flange (64) on the side facing the stop ring (57) has a centering flange (65) with a larger diameter than the piston head (61) which is adapted to its opening.

21. Metering device according to claim 19 or 20, characterized in that the metering piston (52) has a reinforced second part with a gradation, the first stage in the opening (82) in the bottom

(81,111) of the stop body (80,110) is guided and the second stage carries the control button (66), and that the annular shoulder (67) formed by the gradation forms an abutment for the spring (83).

22. Metering device according to claim 21, characterized in that a piston part (61) and the lifting flange (64) carrying the first part of the metering piston (52) is releasably attached to the reinforced second part.

23. Dosing device according to claim 17 and one of claims 19 to 22, characterized in that between the ring flange (74) of the guide (53) and the edge part (84) of the stop body (80) Hubbe limiting means in the form of washers (87,90,100 , 105) are arranged which determine the minimum distance of the stop body (80) from the stop ring (57).

24. Dosing device according to claim 23, characterized in that the annular discs (87) between the

Ring flange (74) and the clamping sleeve (85) are arranged.

25. Dosing device according to claim 24, characterized in that the annular discs (87) have a recess

(88) and a display disc with quantity information is arranged under the ring disc (87).

26. Dosing device according to claim 23, characterized in that the annular disks (90) form non-closed rings and are held between recesses (91, 92) in opposite surfaces of the clamping sleeve (85) and the edge part (84).

27. Dosing device according to claim 23, characterized in that the non-closed annular disks (100, 105) can be plugged onto pins (103) projecting from the end face of the clamping sleeve (85) and the edge part (84) of the stop body (80) is one of the pins ( 103) facing groove (107).

28. Dosing device according to claim 27, characterized in that the annular disks (100) are provided with holes (102) in an arrangement corresponding to the pins ((103).

29. Dosing device according to claim 27, characterized in that the annular disks (105) have an engaging groove (106) facing the pins (103).

30. Dosing device according to claim 18 and one of claims 19 to 22, characterized in that the engaging elements form stroke limiting means which from the inner wall of the second end of the guide (53) projecting pins (114) and each with a pin (114 ) engaged slot combinations each have an axial slot (112) and circumferential slots (113) emanating therefrom at predetermined intervals.