DE33168C - - Google Patents

Description

PATENT OFFICE. \%

This compression ice machine is used instead of the previously used one for evaporation Liquefied gases arriving, such as ammonia, sulphurous acid and so on, carbonic acid used.

The use of carbonic acid for the production of cold has the advantage that carbonic acid does is a much more intense coolant than the gases previously used, so that the Compression pumps with carbon dioxide for the same performance are much smaller than hitherto, and indeed not a sixth as large as the smallest ammonia pumps hitherto. Another resounding advantage is the great cheapness of carbonic acid as a coolant. It costs less than a twentieth as much to fill a carbonated ice machine as it does to fill one Ammonia machine of the same power, and in the same way the costs are reduced occurring leaks.

Furthermore, in the case of carbonic acid, the inconvenience is avoided that more is caused by the leaks or less unpleasant and unhealthy gases get into the work area and also be absorbed by the ice.

The devices necessary for the use of carbonic acid are essentially through the required high tensions of the carbonic acid, which depending on the The temperature of the cooling water can be up to 75 atmospheres, so that the known constructions from cold steam machines, such as those for ammonia, sulphurous acid or Aether are used, practically not appropriate when using carbonic acid are. To avoid gas losses through the stuffing box when compressing the A number of proposals have already been made, which essentially relate to the application of gases two stuffing boxes run out, which form a chamber between them, which absorbs a barrier fluid, or from which that which has passed through the inner stuffing box Gas is constantly sucked off by means of a special pump. I will take the former route, but will not let you know how Linde (Patent No. 1250), the liquid underneath higher pressure than the highest compression tension, neither do I escaping gas back into the suction chamber of the pump (Patents No. 5312 and 21971), but I keep the pressure in the chamber roughly equal to atmospheric pressure by using the gas discharge pipe of the stuffing box chamber connect a gasometer, in which the gas which has passed through the liquid can reach and accumulate, and from which gasometer the gaseous carbon dioxide either with switching off the refrigerator sucked in by the pump or by means of a jet device operated by high-pressure carbon dioxide into the suction chamber the pump is inserted. In this way one achieves that the outer stuffing box of the The pump is under very little pressure (about 50 mm water pressure), so that it is the same can turn out to be very small and no further mechanical devices for returning of the gas or facilities for distilling off the sealing liquid etc. are required. On the other hand, the high suction

Voltage of the pump, which is from 20 to 25 atmospheres, the direct return of the Gases escaping through the inner stuffing box create such a high pressure in the stuffing box chamber make it necessary that for the outer stuffing box possibly the same facilities as they are necessary in the previous compression pumps in cold steam engines. It the device to be patented thus becomes the pump for compressing the gases very much simplified.

When the compressed carbonic acid is transferred from the gaseous into the liquid state, it is desirable to keep the temperatures as low as possible, since with increasing temperature the pressure at which the condensation occurs is considerable grows and the work involved in compressing increases significantly accordingly.

So z. B. the carbonic acid at o ° already liquid under a pressure of 36 atmospheres, while at 30 ⁰ about 73 atmospheres are required to convert the gaseous carbonic acid into the liquid state.

In order to cool the compressed air as much as possible when the machine is in operation To achieve carbon dioxide and to keep the tension as low as possible, I switch between the condenser and refrigerator an apparatus in which the from the refrigerator incoming carbonic acid is used as a coolant for the compressed carbonic acid. This apparatus is at the same time set up in such a way that it serves as a storage room for a larger one Quantum of ready-cooled, liquid carbon dioxide is used.

An ice machine provided with these facilities is illustrated in the accompanying drawing by FIG. 1 in its overall arrangement, namely A denotes the compression pump, B the condenser, C the cooler, D the refrigerator and E the gasometer for collecting the gas escaping from the stuffing box chamber. The body of the pump A, Fig. 2 and 3, is expediently surrounded by a container ^ for receiving cooling liquid and the pump piston must also be supplied with cooling liquid which is introduced through tube χ into tube y attached inside piston K and through tube u leaks, be cooled.

The stuffing box chamber 0 communicates with the container b for receiving the lubricating liquid through a U-shaped tube r and with the interior of the gasometer E through a tube h , so that the carbon dioxide escaping from the inner stuffing box s reaches E through tube h and accumulates here.

Since the voltage in chamber 0 is only equal to the atmosphere or only slightly exceeds it, the outer stuffing box t can very simply be constant.

Instead of forming the stuffing box cover as a chamber for receiving the lubricating liquid, the chamber 0 used for this purpose can also consist of a box A ¹ , FIGS. 2 a, 3a and 3 b, which is ^{screwed to the flange C 1 of the pump cylinder and the} Cover B ^{1 of} the main stuffing box surrounds it. This arrangement ensures that the carbonic acid which otherwise escapes from the outer circumference of the main stuffing box at a ¹ cannot be lost, but is also collected.

In order to tighten the main stuffing box cover B ¹ or to replace the rubber ring, the box A ¹ must then be removed, but this does not require much effort.

Oil or glycerine is expediently used as a sealing liquid for the gasometer. The highly heated carbonic acid compressed in the pressure pump A passes through tube α, FIG. 1, to the tubular condenser B of known construction and from this through tube c to the cooler C, the device of which can be seen particularly in FIG. The pipe c first merges into a serpentine m which is connected to the upper part of the container F by pipe η .

From the lower end of the same, the pipe d leads . with valve or cock e after the refrigerator of known construction. Here the liquid carbonic acid is converted into a gaseous state and thereby extracts heat from the cold liquid. The still very cold, gaseous carbonic acid then returns through pipe / to the cooler C , where it passes through the coil ρ , which is arranged between the container F and the coil m .

The snakes and ρ m, and the container F are surrounded by a salt solution; so that the the BEZW by ρ sweeping, still very cold aerated m and jFfliefsenden comprimirten. liquid carbonic acid with the mediation of the salt solution still removes significant amounts of heat and in this way a considerable decrease in temperature and pressure occurs.

As a result, by using this cooler, the compression work is kept to a minimum reduced.

The carbonic acid which has been active in the cooler C is fed back to the suction chamber of the pump A through pipe g.

The carbon dioxide that accumulates in the gasometer E from the main stuffing box s is temporarily returned to the

Claims (2)

machine, and this can be done in two ways. Either the connection between cooler C and refrigerator D is interrupted by closing the cock or valve e in pipe d, the tension in suction pipe g is depressed by the action of pump A until simple atmospheric tension prevails in it, and then pipe g by means of it with the pipe i connecting the gasometer E with tap k after opening the latter, the carbonic acid is simply sucked up from the gasometer and the latter is pumped empty, whereupon k is closed again and e is opened, or the carbonic acid accumulated in E is introduced without interrupting operation by means of a jet device q switched into the pipe i, which is fed by means of high-tension carbon dioxide from about 60 atmospheres. This carbonic acid can be taken from the pressure pipe α through pipe ν with cock w, Fig. 1, but in this case the direct connection of this pipe i with pipe g must be interrupted, for which purpose a cock / can serve. The filling of the machine with carbonic acid is carried out in such a way that carbonic acid of any voltage is supplied to the suction chamber of the pump through a valve: To replace the carbon dioxide lost in the factory, if liquid carbonic acid is available, it is fed into the suction chamber of the pump expand. If, however, only carbonic acid of atmospheric tension is available, this is allowed to enter the gasometer and proceed as indicated above. Although in the foregoing only carbonic acid is spoken of, it is obvious that the devices described can also be used when the machines are operated with other working fluids. Patent claims: 1. In cold steam engines, the device to reduce gas losses at the stuffing box of the compression pump. consisting of the compound of the chamber filled with a Sehmierflüssigkeit ο with the gasometer E h through pipe in which gasometer escaping from the stuffing box gas accumulates and from which it temporarily the pump A is either simply by suction with the exclusion of the refrigerator or by using a Jet blower is fed back by means of high-tension carbonic acid. 2. In cold steam engines, a cooler connected between the condenser and the refrigerator with a storage tank F for collecting the working fluid, in which cooler the working fluid in the tank F and the pipe system m is separated from the expanded, gaseous working fluid flowing through the pipe system ρ from the refrigerator Liquid that is difficult to freeze (saline solution) is cooled in order to keep the voltage in the machine within the lowest possible limits and to reduce the work involved to a minimum. For this purpose 2 sheets of drawings.