DE648249C - Method for switching off the stove heating of intermittent absorption refrigeration apparatus - Google Patents

Description

Procedure for switching off the stove heating of intermittent absorption chillers The invention relates to intermittently operating absorption refrigerators, d. H. on apparatus which have periods in which refrigerant is off at high pressure an absorbent is driven off, with alternating periods in which the refrigerant is taken up again by the absorbent at low pressure.

It is already known to control such refrigerators by thermostats which, for example, turn off the heating when the cooker temperature exceeds a certain level. If such thermostats are to work well and reliably, they are extremely expensive to manufacture, because a thermostat that should not switch off at # 17g ° E, for example, but safely switches off at # 18o ° C, requires extraordinary delicacy of the construction. In addition, there is the fact that the cooker temperature is also dependent on the outside air in a certain sense. The moment when the stove reaches -f- 10 ° C, for example, occurs earlier in operation. on if the outside temperature is + 3 5 ' than if it is only i5 °. Even then, the thermostat does not separate under similar internal operating conditions.

In order to be able to get by with simpler thermostats, one already has suggested sudden temperature changes due to relocation of operating resources in the apparatus and to let this act on the thermostat, and one has for this purpose refrigerant overflowing from the evaporator used; that's a quick cool-down caused a thermostat, which under the influence of cooker vapors on higher Temperature was kept * This control of the thermostat by a sudden However, cooling is subject to certain potential for disturbances. It can e.g. B. enter, that the cooker temperature and thus the temperature of the cooker gases above normal is, so that the cooling of the thermostat is not sufficiently great to ensure that the heating is switched off. The invention works with a sudden Raising the thermostat and essentially consists in reducing it by decreasing of the level of boiled absorption solution, columns of liquid from operating resources relocated, so that liquid locks tear open in the apparatus and thereby the stove gas new gas paths are opened so that hot cooker vapors suddenly hit the thermostat act, which triggers its reversal activity.

The figure shows an embodiment of the invention.

In the figure io denotes the cooker, ii the condenser, 12, the evaporator, 13 the absorber of an intermittently operating refrigerator. With r4. is the analvser, with 15 and 16 rectifier arrangements, with 17 an equalizing vessel and 18 denotes a collecting vessel.

The cooker io is functional from one chimney i9 traversed, which in any known `` '' way by electric heating cartridges, Gas, petroleum burners, Danipf. or waste heat can be heated.

Cooker io surrounds chimney i9 in the embodiment example de., Nn a tight cling, ul`d, more intimately only as little liquid as possible at the same time to have to be hot on the] roll cooker temperature. The lower part of the chimney i9 is surrounded in a manner known per se by a pump spiral 2o from which a conveying pipe 21 leads into the gas rattin of the cooker. Let it be as non-limiting, To facilitate understanding, assume that the apparatus with water and ammonia works and is filled to level line 1 when it is first filled may be. In practice, the apparatus is filled quite so high ”- earth; but must rope the later-described liquid lines connecting the absorber and digester in any case rllit liquid filled rope].

If the heating source of the cooker is switched on for the first time, liquid is pumped up through the pump coil 20 by gas bubble action, so that the liquid level in Analyzer 1.1 tends to fall to the level la shown, while the Koc level first correspondingly to the level la shown strives to rise. However, the actual rise in the cooker level to hell la is counteracted by the overpressure building up in the cooker, which will be described later. The gas formation in the cooker, which begins with the further supply of heat, now increases the pressure in it, so that the cooker pan passes through the hurried line 22 and bubbles through the liquid in the small auxiliary vessel 23 to enter the analyzer 1-4 . into which the cooker steam expels solvent vapors from the rich solution it encounters. From the analyzer i.1, the somewhat dried steam passes through the line 2.1, which is slightly inclined to improve the return flow of the separated water quantities and which surrounds the rectifier part of the liquid temperature changer (in which the steam is further dried by cooling), after which the 30 narrow conduit 25, which opens in a U-shape into a St.tiirlrc.lir (). The rising digester pressure pushes the liquid in the narrow line 25 downwards, so that the liquid iiii standpipe 26 adjusts itself to the level lb shown, for example. If the digester pressure has risen sufficiently, the digester drip bubbles through the liquid in the standpipe 26 and becomes all of the baffle plates 2; and 28 ini standpipe 2 () further dried. From the upper part of the Starielrolires .2 (, the 10- steam in the arbitrarily designed, two for example cooled by cooling flanges , Condenser 1 t, full where from the condensate '.., p #. the @r jacket vessel 2c9 enters in which it is in In a known manner, the cleat plates 28 ilil stand- r «hr 2 (i cools. That is in the jacket space 29 Any condensate attached is blocked by the% increasing pressure in the boiler in the rer part of the shell space 29 outgoing Line 3o aiiftv: irts into the evaporator 12 pressed, in which it gathers. The in Cooker degassed poor solution flows through a line 31, which ini embodiment through the lower part of the fluid in the atia- ly-sers i.] is passed through and the upper gas-filled part of the analyzer 1.1 serpentine surrounds freakily. ' But is this type of leadership The poor solution is not a requirement. It can be advantageous to the lower "feil des Analyzer i-. to make tight do small there Having amounts of fluids; so that the advantageous heat exchange also in other rer known manner can be carried out. The line 31 for the poor solution is then through the rectifier 15 i111 inside a Tube 32 for the rich solution, which- art, da]] i111 1 electifcator a triple heat no change takes place, d.11. between steam, rich and poor solution. Front rectifiers gate 15 from the line 3i runs for the poor solution in the interior of the weclislers 33, full your atls them at 3.4 in the lower] part of the absorber 13 occurs. From the- sorber can be used in any known manner, for example by cooling flanges, cooled and be designed in any way. The from The pressure exerted by Kocherdanipf causes Solution in the ini embodiment of the line 3.1 branching ascending Line 3 () is pushed up. In this line As a result, the liquid rises to them fills the sam- 18 and then increases in progress setting of this line 3 (1 a little further all. The increase in the fluid in the line tllllg 36 takes place up to a mirror height that is so high above a stove top lies, the voice of the little liquid column i111 vessel 23, the column of liquid. i111 Standpipe "2 (@ and the Drticksätile des Condensate in line 3o taking into account inspection of the special weights of these Columns is as long as the liquid pillar of the Alrsorl) tionl ('istuig i11 of the line 36. When starting up (it apparatus 4 1 _) for example teigt the S-Ille in de) - 1-e «t""93 ( wise up to height] b. The one to fill the ztvcckmäl: @ig narrow line 3l # and the Sam- inelgefälies 18 the liquid required is next by corresponding _Unahine der 1'lltgglglit'ltglnellge 1111 .illal @ 'gel "delivers 1.1 g%. Since the digester level is above the level of the absorber due to the action of the pump 2o, the solution in the absorber is driven by a line 35 branching off from the upper part of the absorber via the outer tube of the temperature changer 33 and duct 32 to the analyzer 14 and thus to the digester io flow back. Especially since there is a pressure in the analyzer 14 that is lower than the actual digester pressure around the small column of liquid in the vessel 23, a rich solution must be drawn from the upper part of the absorber through lines 35 and 32 according to the flow of this column of liquid and the flow resistances in the lines run into the analyzer 14, where this solution runs over per se known impact plates 38 of the steam flow against the lower part of the analyzer and dries the cooker steam in the process. From the analyzer 14, the rich solution flows through a line 61 to the pump 20. The cooking gases flowing through the vessel 23 cause the liquid to boil over, particularly at the beginning of the cooking period, i.e. when the pressure is low and the gas bubbles developing are correspondingly large, so that level fluctuations in the vessel 23 occur. In practice, these fluctuations cause the level in the digester to rise accordingly, so that a backflow-rich solution must enter the analyzer 14 even if the liquid in the vessel 23 is boiled out, that is, pressure equalization between the digester and the analyzer 14.

The amount of the absorption solution circulating between the cooker and the absorber is reduced by the amount of the amount of condensate gradually accumulating in the evaporator 12 during the heating period. Since the absorber 13 is constantly air-cooled, no gas formation can occur in itself. Therefore, the amount of liquid collecting in the evaporator 12 gradually empties the equalizing vessel 17 and a corresponding sinking of the spieim through a liquid line 48 gel 21 and a gas line.: 19 analyzer connected to it to level Ic. Of course, the compensation vessel 17 can also be combined directly with the analyzer 14 to form a single vessel. If the level in the compensation tank 17 and in the analyzer 14 has fallen to the level line Ic during operation, i.e. the evaporator 12 is filled with condensate, a thermostat device switches off the heating of the cooker.

This thermostat device will be described in more detail below. A line 39 leads from the gas head of the cooker to a, for example, cylindrical one Vessel 4o into which a thermostat sensor element 41 is inserted in a manner known per se is. But this training is not a requirement. A steam line leads in front of vessel 4o 42, which is expediently provided with a U-shaped part 43, downstream of the analyzer 14. The sensor body 4i of the thermostat is connected by a conventional pressure line 4.a. with a bellows 45 or the like. Connected via a valve rod 46, for example Gas valve 47 controls in a gas line. The detailed training of the thermostat, its parts and their most appropriate arrangement need not be described in detail as similar thermostat arrangements are state of the art. So long the level in the compensation tank 17 and analyzer rd: is still above the line I c, is the cooker vapor through the liquid in the line 42 and in the (pipe 43 of the Path closed after the analyzer 14, so that no Steam enter the cylindrical vessel 40 and heat the thermostat sensor element 41 can. Sinks. but the level in the analyzer 14 is at the level I c, so the liquid lock 4.3 broken, and Kocherdarnpf then also flows through line 39 to the vessel .4o and through line42 after the analyzer 14 .. This is the thermostat 4 1 quickly and suddenly heated and the gas valve 47 closed by him. The cooling period can start.

The cooling of the no longer heated digester 10 and the lines 22 and 42, the analyzer 14 and the steam line 2 which surrounds the rectifier 15 causes a pressure reduction in the digester system. The liquid columns in the lines 30, 26 and 36 generated by the previous overpressure 'of the digester therefore drop. The condensate falling in the line 3o collects in the cooling jacket 29. The liquid column now falling in the standpipe 26 rises accordingly in the narrow line 25. An amount of poor solution corresponding to the amount of liquid in the line 36 and in the vessel 18 is first caused to overflow into the analyzer 14 through the line 35 and the outer roll of the temperature changer, in which it runs over the plates 38, due to the drop in the liquid columns . This relatively cold, because it was cooled in the absorber 13, and the poor amount of liquid now running into the analyzer 14 causes a very strong absorption of the gas still in the analyzer, so that the negative pressure in the previous positive pressure system is reduced very quickly and significantly. As a result of this cold, poor liquid flowing into the analyzer 14, the pressure drops so quickly that just a few minutes after the heating has been switched off as a result of the pressure decrease, the refrigerant vapor that is now in relative pressure in the evaporator 12 under the rest of the system is formed through line 36 The damming up of the solution in the line 36 and in the collecting vessel 18 thus causes a very rapid pressure reduction in the alveolar 14 when the heating is switched off, because the liquid standing on the plates 38 is renewed very quickly so that this liquid cannot lose its absorption capacity due to the thin layer of concentrated solution which otherwise forms on these plates for example a rise in the level in the compensation tank 17 and in the analyzer 14 up to about mirror fleas 1I a.

As shown in the exemplary embodiment, the line 36 is connected to the line 34, the poor solution leads from the cooker to the absorber. That in the short one ascending line portion of the line 34 ascending gas exerts a suction effect on the rest of the solution in the cooker, the level of which gradually for example, decreases to the level Il a, while the accumulation in the absorber Solution continues through line 35 into the analvser 14. So it also comes during the absorption solution from the cooker to the absorber, which is caused by the pumping action of the through Line 36 flowing in evaporator gases is effected. The evaporation of the refrigerant condensate in the evaporator 12 continues until almost all of the refrigerant in the evaporator 12 has evaporated. The equivalent of the amount of evaporated liquid must therefore im Absorberystein appear again, and indeed gradually fills up due to its suction or the overpressure effect of the evaporator of the analyzer 14 with enriched liquid from the absorber 13 until the level in the analyzer at the end of the cold period and has risen to the level II b in the compensatory geiss 17, whereby the permanent Filling of the vessel 23 is ensured. The negative pressure in the analyzer 14 causes Furthermore, that liquid is sucked up from the tube 26 via the U-tube 25 accordingly so that the level in the standpipe 26 falls approximately to the level 1I a. Through this the filling may be there, for the actual Operation of excess amounts of liquid in the standpipe 26 via the line 15 after the AnalYser 1.4 drained. Sohald the condensate in the evaporator 12 or completely has almost completely evaporated, so (leave only small amounts of the 14 and the two rectifiers 15 and ifi entrained amounts of absorbent remain in the evaporator, the evaporator temperature rises, and this increase is through a second. for example arranged on the evaporator 12 therniostat arrangement Any known design via a bellows 5o and a valve rod 51 on a second valve 52 transferred in the gas line. The control process initiated by the Increasing the cooling temperature is triggered, requires that see the second valve 52 opens in the gas line. Since through the line during the entire cooling period 39 no more steam is flowing, the thermostat sensor is in the meantime 41 has become cold again and therefore has the first valve [7 in the gas line opened again, so that now both valves 47 and 52 in the gas line are open and the heating is re-ignited by the usual eternal flame. The valve 47 is therefore at the end of the digester period, when the level in the compensation tank 17 has dropped, suddenly closed, and this valve may remain closed because of the insulation of the vessel 4o and thermostat 41 until, for example 5 minutes later the cooling period begins, which in turn closes valve 52, so that no heat can be supplied to the device. After a while the thermostat opens 41 the valve, 47, while the valve 52 is closed during the refrigeration period remain. Only when the cooling capacity drops and that controlled by the second thermostat The cooling temperature rises, valve 52 opens and the supply of heat to the apparatus is switched on back on. Instead of the gas thermostat shown schematically, it goes without saying that in the case of a different heat supply, a corresponding training, for example via electrical Toggle switches or the like can be used.

When the heating is switched on again, the process is essentially repeated. which comes about the first time you start. The difference is essentially that the cooker level is somewhat lower during the periodic operation at the beginning of the cooking period, for example at the level 1I a, and that the amount of liquid in the standpipe 26 is less than when it was first started, so that the liquid in the Standpipe 26, for example, only rises on line III. The vapor pressure of the digester has thus then in the ordinary operation periods only the i short column of liquid in the vessel 23 and the small column Il f in the standpipe 26 as well as to form the condensate column 3o. The liquid column holding the counterweight is correspondingly reduced. in line 36, which consequently rises, for example, only up to level line III.

In the exemplary embodiment, the evaporator 12 is designed as a self-draining evaporator. It can be arranged at a slight incline and is provided with a drain line 53 which opens into the vessel 37 already mentioned. Through this training is achieved; that after the first cooling period in the evaporator 12 remaining amounts of absorbent collect at the mouth of the line 53. If new condensate enters the evaporator 12 during the following boiling period, the remaining absorbent is pressed out of the evaporator 12 through line 53 into the vessel 37, from which it flows back through line 36 into the absorber. To relieve the pressure of the vessel 37, it is connected to the upper part of the evaporator by a gas line 54. In the exemplary embodiment, the evaporator is also designed as a continuously cold-transferring evaporator. For this purpose, the evaporator r2 @ is provided with a jacket container 55 which is connected to a container 57 via a line 56. The container 57 contains a dry or solid absorbent in which a secondary refrigerant is dissolved. The container 57 is provided with two evaporation and condensation systems 58 and 59. Both systems 58 and @g are partially filled with an evaporable liquid. The absorption heat occurring at times in the container 5 @ is dissipated by the system 59 in a known manner to the outside air, while the in the container 57 -in the. Cold resulting from cooling periods is used by the system 58 as useful cold, for example for cooling cabinet air or for making ice. Also in the cooling jacket 55 surrounding the evaporator 12, a partial evaporation and condensation system 6o, which is filled with evaporable liquid and which is intended to transmit useful cold, is arranged on its bottom. In the cooling periods in which the evaporator 12 generates cold at low temperatures, refrigerant is sucked out of the absorbent in the container 57, which is condensed by the evaporator 12 in the container 55 and collects at the bottom of this container. The cold caused by the evaporation of the secondary refrigerant in the container 57 is through. the system 58 made usable. In the cooking periods of the apparatus in which there is no cold in the evaporator 12, the condensate of the secondary refrigerant, which is in the bottom of the container 55, is sucked up again by the absorbent in the container 57 through line 56, and the evaporation cold of the secondary refrigerant is through the system 6o is used as useful cooling. However, both the vaporizer and all other vessels of the exemplary embodiment can be given a training other than that shown without affecting the essence of the invention. The apparatus parts can also be arranged at any other height to one another, e.g. B. the condenser can be arranged above the evaporator if it is only ensured by appropriate routing of the connecting lines that the liquid columns necessary for operation are formed and maintained.

Claims (5)

PATENT CLAIMS: r. Procedure for turning off the stove heating intermittent absorption chillers where entering the machine Relocating equipment suddenly changes the temperature of a thermostat, characterized in that by (the sinking of the level .of boiled absorption liquid relocated the liquid-time columns of equipment and by tearing open liquid locks new gas paths are opened through which hot stove vapors flow and with your Thermostats are brought into contact, causing a sudden increase in Temperature of the thermostat takes place. 2. Procedure for switching off the stove heating according to claim r, characterized in that the displacement of the liquid columns at the same time the absorption process is initiated. 3. Absorption chiller for Execution of the method according to claims r and 2, characterized in that the Thermostat is ang @ eordmet in a refrigerant path outside the cooker. Absorption refrigerator according to claim 3, characterized in that the outside The refrigerant path lying in the cooker carries steam. 5. Absorption chiller according to Claim 3, characterized in that (let the thermostat influenced by the cooker by a thermostat under the influence of the cooling supplied by the evaporator is supplemented.