DE83734C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

Carbonic acid in liquid form.

The present invention relates to a cooling system in which the volatilization of the Compressed carbonic acid bound heat is used to generate cold. The carbonic acid is sucked out of the gasometer by means of a suction and pressure pump and arranged in the manner of a cooling coil Pressed condenser, where the heat generated during compression is simultaneously transmitted through water is absorbed by a low temperature. The condenser is condensed respectively liquid carbon dioxide in the actual, the snakes for the liquid to be cooled containing cooling apparatus (refrigerator) drained, where they volatilized BEZW. evaporates and has a cooling effect. The carbonic acid is then extracted from the refrigerator by another suction and Pressure pump sucked off again and for further use in normal carbon dioxide bottles or pushed back into the condenser.

Fig. Ι shows the side view of the cooling system,

Fig. 2 shows the outline of the system in partial section and

Fig. 3 shows a pressure regulator which equalizes the pressure in the condenser and in the case It is used when the carbon dioxide extracted from the refrigerator enters the condenser is pushed back.

The suction and pressure pump A sucks the carbonic acid out of the gas collector B and presses it into two helically wound pipe coils D and D ¹ (condenser) that are connected to one another and arranged in an iron, cylindrical vessel.

Cooling water of about 12 ° C. runs around these pipe coils DD ¹ , which absorbs the heat generated by pump A.

A line leads from the condenser coil D ¹ to the actual cooling device G (refrigerator), which has a tap F for regulating the inflow. In the cooling apparatus G , a cooling coil H of larger caliber is arranged, which is connected to a second suction and pressure pump A ¹ . The snake H is pumped out through the latter, so that when the tap F is opened, the liquid carbonic acid passes over, evaporates in the snake H, and heat is withdrawn from its surroundings.

The carbon dioxide sucked out of the coil H by the pump A ¹ is either pushed back into the condenser Z) ¹ through the intermediary of the line α or into bottles I that are kept ready; The latter is made possible by the fact that new carbon dioxide is always sucked in from the gas collector B by the pump A and pressed into the condenser coil D. In the gas collector B is always carbonic acid gas in great quantity available.

^{The one} in FIG. 3 serves as an indirect connection of the condenser coils D and D 1

Pressure equalizer shown, which has the purpose of equalizing the pressures in both pipe coils D and D ¹ .

It is arranged between the condenser coils DD ¹ separated from one another by a sheet metal wall n> and is connected to the inner ^{condenser coil D 1} by pipe η and to the outer condenser coil D by pipe ρ . It consists of a Gufscylinder O with a stuffing box-like attachment L in which a piston K moves. The piston K is designed in such a way that in front of and behind it a chamber N and iV ^{1 is} formed in the cylinder O , into which the tubes ρ and η open. The lines ρ and η are indirectly connected by the tubes q and r, so that, depending on the position of the piston K, the carbonic acid can be transferred from the coil D to D ¹ and vice versa.

The mode of operation of the pressure regulator is as follows:

In the rest position of the piston K, the same blocks both condenser coils D and D ¹ from one another.

If the condenser coil D is now filled by the pump A and the through valve Z ₁ is opened, the piston K pushes to the right and opens the connecting pipe q until the pipe η, which is connected to the inner condenser coil D ¹ , is the the same pressure as in pipe section D prevails.

As soon as the pressure gauge M 65 Atm. shows, both coils D and D ^{1 are} sufficiently filled with carbonic acid so that they can be used for cold preparation. You open the tap F and let the carbonic acid pass into the evaporator.

The pump A ¹ sucks the carbon dioxide out of the evaporator and pushes it back into the bottles IP that are either kept ready or into the condenser D ¹ .

In the latter case, overpressure may arise in the condenser D ¹ compared to the condenser D. Then the excess carbonic acid should pass back into the condenser D by moving the piston K to the left.

This case can occur in particular because both pumps A and A ¹ should work independently of one another and their performance is not the same. As soon as the pressure gauge M is above 65 Atm. shows, you shut off the three-way valve Z in such a way that the carbon dioxide from the coil D resp. The connecting pipe ρ can be filled directly onto bottles through the pipe s or discharged into the open air.

By switching on the pressure equalizer with the device, so that the carbonic acid of the coil D can be drained directly through the pipe s and filled into bottles or used in some other way, it is possible to close the circuit of the cooling system, so that with the one in the coil D ¹ contained carbonic acid can be worked for itself.

Claims (1)

Patent claim: Machine for cold production by means of carbon dioxide and for the storage of excess carbon dioxide in liquid form, characterized by the arrangement of two connected suction and pressure pumps A and A ¹ , of which A sucks carbon dioxide from a gas collector and into one exposed to the action of a cooling agent, from two with Connected coiled pipes D and -D ¹ presses existing condenser, from which the liquid carbonic acid can be drained and volatilized into the cooling coil H as required, while the suction and pressure pump A ¹ sucks the volatilized carbonic acid from the cooling coil H again and either on bottles / or pushed back through a tube α into the condenser Z) ¹ for repeated use, so that it can be used with this alone without the aid of further carbonic acid to be removed from the gas collector. 1 sheet of drawings.