|Publication number||US3797709 A|
|Publication date||Mar 19, 1974|
|Filing date||Jul 12, 1972|
|Priority date||Jul 12, 1971|
|Also published as||US3773259|
|Publication number||US 3797709 A, US 3797709A, US-A-3797709, US3797709 A, US3797709A|
|Original Assignee||Ivanovich A|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (3), Referenced by (12), Classifications (16)|
|External Links: USPTO, USPTO Assignment, Espacenet|
United States Pat ent 1 Ivanovich VOLUMETRIC METERING APPARATUS  Inventor: Anatoly Ivanovich, Bratislavskaya ulitsa 26, kv. 22, Zverev, Kiev,
22 Filed: July 12, 1972 211 Appl. No.: 271,139
 Foreign Application Priority Data July 12, 1971 U.S.S.R 1675700  US. Cl. 222/194, 222/334  Int. Cl B67d 5/54  Field of Search 302/49; 222/194, 373, 334,
 References Cited UNITED STATES PATENTS 3,096,942; 7/1963 Conrad-..lr... ..22 2 /194,x
[451 Mar. 19, 1974 3/1963 Crafts 222/373 X 2,818,200 12/1957 Webb et a1. 222/194 Primary Examiner-Even C. Blunk Assistant Examiner-H. S. Lane Attorney, Agent, or Firm-Holman & Stern [5 7] ABSTRACT An apparatus is disclosed comprising a cylindrical body housing a plunger having a measuring space which, as the plunger is moved by compressed gas, in one of its extreme positions communicates with a feed hopper, while in the other extreme position of the plunger, the measuring space communicates simultaneously with a discharge standpipe and a plenum space in the body in order that the metered material may be blown out of the measuring space by com- .pressed gas.
5 Claims, 4 Drawing Figures l VOLUMETRIC METERING APPARATUS BACKGROUND OF THE INVENTION This invention relates generally to an apparatus for transferring, in metered quantities and at a high rate, liquid and finely divided solid materials from one pressure-temperature zone to a zone of higher pressure and temperature, and more particularly to a volumetric metering apparatus.
There are numerousphysical, chemical and other processes which are operated at elevated pressures and temperatures and require stringent metering of liquid or finely divided solid materials utilized either as raw material or as a catalyst for the reaction, or else as a regulating vehicle to obtain some specified properties of the product.
In some cases, as while polymerizing synthetic rubber, solid materials (raw material and catalyst) are to be blended with a suitable liquid regulator and agitated to fonn a desired paste which is then injected in metered amounts into the reaction zone of high pressure and temperature.
This invention may be most successfully employed in apparatus for explosion treatment of materials, in particular for applying by explosion protective coats of both refractory and low-temperature materials.
Those skilled in the art know metering devices of various purposes, such as star feeders, multiple high pressure lock hoppers, all of which supply the material in metered quantities to the reaction zone.
Thus, there exist apparatus for transferring finely divided solids, as for example coal powder.
Such devices comprise a casing wherein there is a plunger member coupled with a mechanical or other type of drive means by way of a coupling member. The charged material is fed by compressed air to a measuring space defined between the end of the casing and the end of the plunger member.
Thus, the transfer of a metered amount of the finely divided solid material to-the reaction zone consists in a longitudinal displacement of the plunger, with air from a separate source being simultaneously blown in through annular passages disposed betweenthe casing and the plunger. The plunger is retracted to its feed (or discharge) position by a special drive means (cf U.S. Pat. No. 3,400,985).
A serious disadvantage of such apparatus is their inability to provide an adequate degree of precision in material metering insofar as the measuring space design features permit a certain quantity of material to stay in it after discharge in spite of an arrangement for additional scavenging of the measuring space.
Besides, typical of such devices is a considerable loss of driving power to overcome friction between the sealing and the plunger arising while the plunger is in motion, as well as a considerable rate of compressed air consumption, which adversely increases power requirements.
Yet another disadvantage of such devices is their complex design which includes additional intermediate members to compensate for the coupling rod displacement arising while the plunger is in motion.
Still another disadvantage consists in that the considerable number of mechanical elements required by the construction of such devices reduces their overall reliability.
SUMMARY OF THE INVENTION It is an object of this invention to provide a volumetric metering apparatus having a measuring space such that would ensure precise metering of material with a minimal consumption of power for the transfer of the metered material to a zone of high pressure and temperature.
Accordingly, there is provided a volumetric metering apparatus comprising a hollow cylindrical body communicating with a feed hopper and with a discharge standpipe, wherein compressed air imparts a reciprocal motion to a plunger transferring thereby a quantity of the material which fills the measuring space.
According to the invention, the measuring space is provided in the plunger such that in one of the latter's extreme positions it communicates with the feed hopper and is charged, while in the other extreme position of the plunger stuffing box the measuring space communicates simultaneously with the discharge standpipe and with a plenum space of the cylinder, wherefrom compressed air is supplied to blow the material from the measuring space into the discharge standpipe.
Such a design, on the whole simplifying the apparatus embodiment, permits precise metering of the material.
It is preferred that the plenum space of the clylinder should communicate, via a conduit, with a through passage in the cylinder body aligned with the discharge standpipe hole.
It is also preferred that the measuring space should be T-shaped, with one end thereof communicating at the instant of charging with the feed hopper, while the other two ends of the T-shaped measuring space communicate at the instant of discharging with passages in the body of the cylinder communicating, one with the plenum space, the other with the discharge standpipe.
Such an embodiment allows precise material metering, strict fixation of a batch in the measuring space, as well as displacement and blowing out of the batch into the discharge standpipe with compressed gas from one source.
There may be bushings fitted into the cylinder ends to limit the extreme positions of the plunger and having passage means for the supply and venting of compressed gas.
The cylinder space opposite the plenum space may be fitted with a spring retracting and fixing the plunger in the charging position.
Such an arrangement provides for a reliable operation of the apparatus.
In order that the plunger should be speedier retracted to the charging position, the cylinder space housing the spring may periodically communicate with the compressed air source.
BRIEF DESCRIPTION OF THE DRAWINGS The invention will be better understood from the following description of one of the possible embodiments thereof taken in conjunction with the accompanying drawings, wherein:
FIG. 1 is a schematic representation of a volumetric metering apparatus in accordance with the present invention;
FIG. 2 is a longitudinal section of the apparatus of FIG. 1 in the charging position;
FIG. 3 is a sectional view taken along the line III-Ill of FIG. 1; and
FIG. 4 is a longitudinal section of the apparatus of FIG. 1 in the discharging position.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT The apparatus is intended for volumetric metering of, above all, finely divided powdered materials in installations requiring accurate batching and subsequent transfer of the batch to the reaction chamber of high pressure and temperature.
The apparatus according to this invention comprises a gas-tight hollow cylindrical body 1 closed at both ends (FIG. 1) housing a plunger whereto compressed gas imparts a reciprocal motion.
A feed hopper 3 and a discharge standpipe 4 (FIG. 2) which communicate in common with the inner space of the body I are mounted on the cylindrical part of the body 1, with the standpipe 4 being disposed in a plane normal to the axis of the feed hopper 3 (in FIG. 2 the standpipe 4 is shown superposed on the drawing plane).
The plunger 2 divides the inner space of the body 1 into two spaces: A plenum space 5 whereto compressed gas is supplied, and an opposite space 6 which houses a spring 7 one end whereof rests against an end 8 of the body 1, while the other end of the spring rests against an annular recess 9 on end 10 of the plunger 2.
The plenum space 5, via an annular conduit 12 fitted in a hole 11 of the body 1 (conduit 12 in FIG. 2 is shown turned), communicates with a through passage 13 in the body 1 which is aligned with an inlet hole 14 of the discharge standpipe 4.
A changeable bushing 31; is fitted in a feed line 3a of the hopper 3. The batch size can be varied by choosing bushings 3b of an appropriate diameter.
A T-shaped measuring space 15 (FIG. 3) defined by two intercommunicating passages: a diametrical through passage 16 and a radial passage 17 perpendicular thereto, is formed in the plunger 2.
The radial passage 17 of the measuring space 15 at the charging instant communicates with thefeed line 30 of the hopper 3, whereas the diametrical passage 16 of the measuring space 15 at the instant of discharging (FIG. 4) communicates by way of one end 18 thereof (FIG. 3) with the passage 13 (FIG. 2) in the body 1 and via the annular conduit 12 with the plenum space 5, while communicating by way of the other end 19 thereof (FIG. 3) with the inlet hole 14 (FIG. 2) of the discharge standpipe 4.
Ends 20 and 8 of the body 1 are fitted with bushings 21 and 22 which define with their inner end faces the extreme positions of the plunger 2 and which have passages 23 and 24 for the supply and venting of compressed gas.
As can be seen from FIG. 2, when the plunger 2 is in the extreme left position the distance between the feed hopper 3 and the inner end face of bushing 22 is equal to twice the length of the stoke of the plunger. This distance is shown to be 2h (h indicates the length of the stroke). Also, the distance between the discharge standpipe 4 inner end face bushing 22 is equal to 3 times the length of the stroke which is shown to be 3h.
Further, in FIG. 2 the hole 11 of the annular conduit 12 can be seen to be located at a distance equal to the length of the stroke from the inner end face of bushing 22. This distance is indicated by h. Passage 13 of the annular conduit 12 is also located at a distance equal to 3 times the length of the stroke of the plunger from the inner end face of bushing 22.
The apparatus is actuated by compressed gas supplied from a source 25 through pipes 26 fitted with electromagnetic control valves 27 and 28.
The feed delivery pipes 26 carry compressed gas to the plenum space 5 and to the space 6 of the body I. while through vent pipes 29 exhaust gas escapes into the atmosphere.
The volumetric metering apparatus disclosed herein operates on the following principle.
In the initial position (at the instant of charging), the plunger 2 is in the extreme left position (FIG. 2) at the end 20 of the body 1 wherein it is fixed by the spring 7. In this position, the measuring space 15 is aligned by way of its passage 17 with the feed line 3a of the hopper 3 and is filled with a batch of material A.
As the electromagnetic control valve 27 is opened, compressed gas is fed from the source 25 through the feed delivery pipe 26 to the passages 23 and 24 of the bushing 21 and therefrom to the plenum space 5.
Acted upon by compressed gas, the plunger stuffing box 2 starts moving to the right until it leans against the end of the bushing 22, thereby compressing the spring 7 and letting the gas from the space 6 of the body 1 escape into the atmosphere through the electromagnetic valve 28.
As the plunger rests against the bushing 22 with its end 10, the measuring space 15 will get aligned by way of its passage 16 with the annular conduit 12 and the discharge standpipe 4.
In this position, the plunger 2 opens the hole 11 in the body 1, compressed air will rush at a great velocity into the annular conduit 12 and blow the powder from the measuring space 15 into the discharge standpipe 4.
After that the valve 27 closes, switching to a draining mode, while the valve 28 opens, thereby letting compressed gas into the space 6 of the body 1.
Under the pressure of compressed gas in the space 6 and acted upon by the spring 7, the plunger 2 returns to its extreme left position until it rests against the end of the bushing 21. From the plenum space 5 the gas is forced to escape to the atmosphere through the vent pipe 29.
The measuring space 15 is again aligned by way of the passage 17 with the feed line 33a of the hopper 3, whereupon the above-described cycle is repeated.
Such a working cycle can be repeated several times per second. What is claimed is:
1. A volumetric metering apparatus comprising:
a hollow cylindrical body closed at both ends;
a plunger disposed in the inner space of said body and dividing the same into two plenum spaces communicating with a source of compressed gas, said plunger being reciprocated within the inner space of said body under the effect of the compressed gas applied into said plenum spaces of said body;
a feed hopper communicating with the inner space of said body and mounted thereon at a distance from one of the inner end faces thereof which is equal to twice the length of the stroke of said plunger;
a discharge pipe communicating with the inner space of said body and mounted thereon at a distance from said inner end face which is equal to 3 times the length of the stroke of said plunger stuffing box;
an arcuate pipe having both ends thereof communicating with the inner space of said body, one of said ends being disposed with respect to said inner end face of said body at a distance equal to the length of the stroke of said plunger, the other end being disposed at a distance equal to 3 times the length of the stroke of said plunger said discharge pipe and said arcuate pipe being disposed in a common plane normal to the axis of said hopper; and
a measuring space defined in said plunger so that in one of its extreme positions at said inner end face that communicates with said feed hopper wherecommunicating at the moment of discharging with the plenum space located at said inner end face of said body by means of said arcuate pipe at one end, while the other end communicates with the discharge pipe, said radial passage of said measuring space being disposed normally through said diametrical passage and from it is charged, while in the other extreme posicommunicating with said hopper at the moment of charging.
3. An apparatus as claimed in clain 1, wherein both end faces of the body are fitted with bushings defining the extreme positions of the plunger and having passages for supplying and discharging compressed gas.
4. An apparatus as claimed in claim 1, wherein the plenum space located opposite the inner end face of said body houses a spring facilitating the return of the plunger and its retention in the charging position.
5. An apparatus as claimed in claim 4, wherein the plenum space of said body space housing said spring communicates periodically with the compressed gas source to accelerate the return of the plunger to the charging position.
UNITED STATES PATENT OFFICE CERTIFICATE OF CORRECTION Patent No. 3797709 Dated March 19, 1974 Inventofls) Anatolv Ivanovich Zverev It is certified that error appears in the above-identified patent and that said Letters Patent are hereby corrected as shown below:
"ANAToLY IVANOVICH ZVEREV Signed and sealed this v17th day of September 1974,
McCOY M. GIBSON JR. C. MARSHALL DANN I Attesting Officer Commissioner of Patents USCOMM'DC 60376-P69 FORM PO-105O (10-69) I w as GOVERNMENT PRINTING OFFICE: I969 o-ass-au
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|U.S. Classification||406/74, 222/334|
|International Classification||C23C24/00, B05B7/00, G01F11/10, G01F11/18, C23C4/12, C23C24/04|
|Cooperative Classification||C23C24/04, B05B7/0006, G01F11/18, C23C4/122|
|European Classification||C23C24/04, C23C4/12B, G01F11/18, B05B7/00A|