DE1567429C3 - Device for producing dry ice elements - Google Patents

Description

The invention relates to a device for producing dry ice elements from liquid carbon dioxide with an expansion chamber to which the liquid carbon dioxide, which forms carbon dioxide snow by relaxing, can be supplied from a supply, with a reciprocating piston that compresses the carbon dioxide snow into dry ice, and with one on one The outlet opening for the dry ice is provided at the end of the piston chamber and is closed by a mouthpiece with several perforations, through which strand-like dry ice elements can be pressed out.
Such a device is known from DE-PS 484570. In the known device, the expansion chamber is spatially separated and arranged above the space in which the moving piston finally compresses the carbonic acid snow formed by the expansion of the liquid carbonic acid into dry ice. Liquid carbon dioxide flows continuously through a feed line into a funnel-shaped space above the cylinder surrounding the piston; this space is vented to the atmosphere via a normal opening, so that the carbonic acid gases which are formed at the same time during the expansion escape into the atmosphere without the possibility of further utilization or recovery.

With each return movement of the piston, the expansion funnel with the inside of the cylinder falls through one of them connecting opening a part of the carbon dioxide snow formed under the influence of gravity into the cylinder interior and is then compressed by the piston in the known manner, whereby through a Narrowing of the cylinder wall and a certain amount due to the provided mouthpiece with openings There is backwater of the carbonic acid ice formed.

The mouthpiece jo having the openings is, however, a comparatively complicated embodiment in this DE-PS 484570 assigned, in which initially formed and already compressed Good is fed to a shredding device, which is formed by a vent Gasen gives the opportunity to escape again and the crushed, clumped pieces of carbonic acid snow again a piston-cylinder unit for compression and finally for the formation of Feeds dry ice strands. At the outlet end of this second piston-cylinder unit is then the single strand arranged forming mouthpiece.

In this known device, the considerable loss of carbonic acid gas is very disadvantageous Relaxation, the generally low efficiency that results from the fact that expansion chambers and Kömprimieinheit are separated, as well as the fact that the gases formed are not even can be used for further cooling.

However, another known device is used to generate the escaping gases for cooling of dry ice elements, as it emerges from US-PS 2282460 as known. At this known device initially provides a counterweight acted upon by a lever mechanism Sledge for sufficient compression of the dry ice or the carbon dioxide snow; then after the outlet opening of the expansion chamber is released by the slide further lever, drive and locking devices a saw through the dry ice strand formed guided to separate a block of dry ice from it. The escaping gases get through a porous grid and from this through openings in one the expansion chamber and at the same time the Inside the cylinder surrounding the annular space, so that the entire expansion and compression unit is cooled can be before the gases exit again through an outlet pipe and are therefore lost.

Based on the known devices for the production of dry ice elements from liquid Carbonic acid, the invention is based on the object to provide a device with high Efficiency works and which is able to directly dry ice elements in divided, cube-shaped Generating shape, while being comparatively easy to set up and maintain.

This object is achieved by the invention based on the device as mentioned at the beginning by the ι ο Features of the characterizing part of claim 1.

In the device according to the invention it is advantageous that on the one hand not the cumbersome linkage and working equipment of the device according to US-PS 2282460 are required to dry ice elements to produce in the desired form, but on the other hand a much more precise work and avoidance any carbon dioxide losses can be achieved.

Since new snow is constantly being formed and compressed during operation, the compressed snow presses Snow the formed dry ice plug gradually through the openings of the mouthpiece and forms itself continuously a new plug so that ambient air is prevented from entering the chamber can penetrate although the dry ice cubes are continuously formed. The production is therefore successful of particularly high quality dry ice cubes, with the one separated from the snow in the chamber Gas can be liquefied again and further processed, since it does not penetrate into the chamber Air is polluted.

Further refinements of the invention are the subject matter of the subclaims and laid down in these.

The following is a structure and operation of a preferred embodiment of the invention explained in more detail on the basis of the drawing. It shows

Fig. 1 is a partially broken away device with a schematic representation of it subsequent gas cycle,

FIG. 2 shows a longitudinal section through part of the device according to FIG. 1,

Fig. 3 shows a section along the line 3-3 in Fig. 2, and

FIG. 4 shows a section along the line 4-4 in FIG. 2.

A device 10 for the production of dry ice cubes or dry ice elements 11 from carbon dioxide has a drive 12 with a crankshaft 13, which is of a not shown Electric motor is driven. In turn, it drives a connecting rod 14 that has a piston pin 15 is connected to a guide piston 16. A piston 17 is screwed onto this. The guide piston 16 moves in a bore 18 of a cylinder block 19, so that the piston 17 moves when rotating Crankshaft 13 reciprocated in the longitudinal direction. On the cylinder block 19 is by means of a with flanged connecting pipe section 21, a cylinder housing 20 fixed in which a porous casing 22 designed as a filter tube, preferably made of sintered stainless steel or reinforced, sintered bronze is arranged. The piston 17 runs in a bore 27 with little play the casing 22, which has longitudinal grooves 23 on its outside, and of a helical spring 24 is pressed against a connecting nut 25, which is one with the outlet opening 27 of the casing 22 aligned longitudinal bore 26 has. The two bores 26 and 27 together form the largest part an expansion chamber "C", one end of which by the piston 17 and the other end, as will be explained will be, is closed by a dry ice plug 28, which by compressing carbonic acid snow Has arisen and is partly in the outlet opening 27 and the other part in a Bore 29 of a mouthpiece 30 is located. This has several small openings 31 that are in the Hole 29 open. On the mouthpiece 30 is an angle with the longitudinal axes of the openings 31 forming crusher or deflector 32 mounted, which ejected from the openings 31 strands of dry ice breaks into dry ice cubes 11.

A line 33 leads from the bottom of a thermally insulated storage tank 34 to a valve 35 on the device. The storage tank 34 contains liquid carbon dioxide L. In addition, a cooling coil 36 of a cooling system (not shown) is arranged in this storage tank above the liquid gas. A ring line 37 with a compressor 38 is connected on the one hand to an outlet connection 39 of the cylinder housing 20 and on the other hand at the top of the storage tank 34. A line 33 'containing a valve 33 ν connects the ring line 37 downstream of the compressor to the line 33 downstream of a check valve 37 v. In the course of the line 33 there is a pressure regulator 37 r, a liquid trap 385 and a further pressure regulator 38 r. A line 38c guides the steam from the liquid trap 38a back to the compressor 38.

The valve 35 expediently contains a valve member 40 which is within a widened part 42 has an inclined surface 41. A compression spring 43 presses the valve member 40 against a valve seat 44, if a control rod 45 likewise provided with an inclined surface 45 'is a lower one according to FIG Assumes position, as is the case, for example, in FIG. 1; when lifting the control rod 45 against the action of the compression spring 43 lifts the valve member 40 from the valve seat 44. Like Fig. 1 shows, the control rod 45 is with the help of a hinge lever 47 and two hinge pins 48 and 49 with a bumper 46, the length of which can be adjusted with a lock nut 50. she will actuated by a camshaft 51 with two flats 52 and 53. So that the punch 17 and the valve member 40 are operated synchronously, the crankshaft 13 is via a suitable gear with the camshaft 51 connected.

The stroke of the upper end of the piston 17 extends from the position shown in FIG. 2 to the lower end of the dry ice plug 28. The upper end face of the piston 17 is designed as a trough 54 with a sharp peripheral edge 55. Between a sealing ring 57 and a metallic one . Sealing washer 58 is a split bearing sleeve 56. The sealing washer 58 rests against an inner shoulder 59 of the connecting pipe section 21 and carries 2 O-rings 60. The piston 17 is also surrounded by a U-profile seal 61, for example made of leather, in which an abutment ring 62 is used as an abutment for a compression spring 63 which, on the other hand, rests against an inner shoulder 64 of the connecting pipe piece 21. The U-profile seal 61 is pressed against a metal disk 65, which by means of a

Snap ring 66 is secured. The bearing sleeve 56 is preferably made of polytetrafluoroethylene.

During operation, the drive 12 moves the piston 17 back and forth and opens and closes the valve 35 synchronously with it. The valve member 40 is lifted from the valve seat 44 over an angle of rotation of the crankshaft 13 between approximately 90 and approximately 150 degrees. The valve member 40 lifts off the valve seat 44 when the upper end of the piston 17 is slightly below the upper end of the casing 22. Even if the valve control is set so that the valve remains open over an angle of rotation of the crankshaft of 150 degrees, the valve 35 is expediently closed before the bottom dead center of the piston 17 is reached (FIG. T). When the piston 17 has released a sufficient part of the chamber formed by the casing 22 in the course of its downward movement, the valve 35 opens and liquid carbon dioxide flows from the line 33 into the expansion chamber C, so that it is there as a result of the cooling caused by the expansion Forms snow and gaseous carbon dioxide. The snow collects in the expansion chamber C, while the gaseous carbon dioxide passes through the porous casing 22 into the longitudinal grooves 23 and from there flows through the outlet 39 into the ring line 37, in which the pressure of the gas is increased so that it is in the storage tank 34 can be promoted. When the piston 17 begins its upward movement, the snow in the expansion chamber C is pushed upwards in the direction of the mouthpiece 30 and is continuously compressed, a certain amount of the solid carbon dioxide forming the dry ice plug 28 being pushed out through the openings 31; the dry ice plug 28

ίο is then composed of the holes 26 and 29 remaining dry ice and the last compressed snow together. With every upstroke of the piston 17, dry ice is pressed through the openings 31, so that the deflector 32 constantly produces dry ice cubes 11.

If the device 10 is to be defrosted, the valve 33 ν is opened and relatively hot steam is passed through the lines 33 ′ and 33 into the valve unit 35. The casing 22 is then thawed extremely quickly before the dry ice plug 28 is sublimed, so that the cube production can be resumed immediately after the valve 33 v has been closed. The steam is of course the gas heated to a relatively high temperature, which is also liquefied and solidified for dry ice production.

For this purpose 2 sheets of drawings

Claims (5)

Patent claims: 1. Device for producing dry ice elements from liquid carbon dioxide with an expansion chamber, to which the liquid carbonic acid, which is formed by letting down the carbon dioxide snow, can be supplied from a supply, with one back and forth movable piston compressing the carbon dioxide snow into dry ice, as well as with a provided at one end of the piston chamber and through a mouthpiece with several openings closed outlet opening for the dry ice, through which strand-shaped dry ice elements are squeezed out, characterized in that a) the expansion chamber (C) forms the space that absorbs the piston movement which is followed by the bore (29) with the mouthpiece (30), with a substantial part of the expansion chamber (C) from an inner, porous one also comprising the piston (17) Sheathing (22) with longitudinal grooves (23), which separates the resulting gases from the snow and over them an outlet port (39) for returning the separated carbon dioxide from the expansion chamber enables, and b) that for supplying the liquid carbonic acid a valve (35) which is controlled by the piston movement and opens into the expansion chamber (C) is provided. 2. Apparatus according to claim 1, characterized in that in the region of the outlet opening (31) of the expansion chamber (C) a deflector breaking the emerging dry ice strands (32) is arranged. 3. Apparatus according to claim 1 or 2, characterized in that the liquid carbonic acid valve (35) entering the expansion chamber (C) via connecting elements (45, 47, 48, 49, 46) is coupled to the drive (12) of the piston (17) in such a way that the introduction of liquid carbonic acid takes place during the downward movement of the piston (17) and before reaching the lower one Dead center is interrupted. 4. Device according to one of claims 1 to 3, characterized in that the upper end (54) of the piston (17) is at the dead center of the compression movement at a distance from the openings (31) of the mouthpiece (30). 5. Device according to one of claims 1 to 4, characterized in that the upper end (54) of the piston (17) is concave with a sharp Peripheral edge (55) is formed.