WO2012010705A1 - Method and device for cooling a liquid - Google Patents

Abstract

The invention relates to a method for cooling a liquid, in particular a process water for cooling unset concrete, wherein a cryogenically liquefied gas in a mixing tube (2) is introduced into the liquid flowing through the mixing tube (2), wherein at least a part of the liquid freezes. In the method, the resulting quantity of frozen liquid is regulated via the quantity of cryogenically liquefied gas that is introduced and can be regulated to a content between 0% and 70% of the liquid. The invention makes it possible to produce a water/ice suspension which has a high ice content in a simple manner. It is also possible, by means of the invention, to adapt the cooling power to short-term peak cooling powers that are required by additional processes. Moreover, very efficient energy transfer from the liquid to the cryogenically liquefied gas takes place.

Description

 Method and device for cooling a liquid The present invention relates to a method for cooling a liquid, wherein at least a part of the liquid freezes, and a device for cooling a liquid. The resulting suspension of frozen liquid and liquid can be used as a process liquid in other processes, particularly preferred is the use for cooling water as process water for use in the production of fresh concrete.

For cooling liquids, various approaches from the prior art are known, for example, it is known to cool liquids by means of compression refrigeration machines based on absorption refrigeration processes or by indirect cooling via a heat exchanger. The liquids are often water, lyes, acids, solvents and / or liquid foods. All of the processes named here are complex in terms of apparatus, which makes the described methods particularly uneconomical when a liquid has to be cooled discontinuously and only relatively rarely, because then high downtimes coincide with high expenditure on equipment. In particular, chillers must be oversized when high peaks in refrigeration capacity are required.

From DE 10 2007 016 712 AI a method and an apparatus for producing a suspension of frozen liquid and liquid are known in which the frozen liquid content can be between 0% and 30%. The suspension is produced by introducing a refrigerant-liquefied gas into a container storing the liquid. Due to increasing agglomeration of the ice on the surface of the liquid however, the process in the container is limited to an amount of ice up to about 30%.

The object of the invention is therefore to solve the problems described with reference to the prior art at least partially, and in particular to provide a method and an apparatus with which a suspension of frozen liquid and liquid can be produced, wherein the proportion of frozen liquid continuously is controllable up to a high proportion, and which allow effective cooling.

These objects are achieved with a method and a device according to the features of the independent claims. Further advantageous embodiments as well as a preferred use of the invention are given in the dependent formulated patent claims. It should be noted that the features listed individually in the dependent claims can be combined with each other in any technologically meaningful manner and define further embodiments of the invention. In addition, the features specified in the claims are specified and explained in more detail in the description, wherein further preferred embodiments of the invention are shown.

The objects are achieved by a method for cooling a liquid, wherein a cryogenic liquefied gas is introduced in a mixing tube into a liquid flowing through the mixing tube in a flow direction, wherein at least a part of the liquid freezes.

Water is preferably used as the liquid, in particular process water for the production of concrete, but also acids, such as, for example, sulfuric acid, and lyes in cooling processes in chemistry are used. The cold-liquefied gas can be introduced into the mixing tube as desired, so the gas can, for example, with the flow direction, against the flow of mung direction, but also arbitrarily introduced transversely to the flow direction of the liquid. However, the introduction of the refrigerated liquefied gas in the direction of the flow direction of the liquid is preferred.

Preferably, the mixture of refrigerated liquefied gas and liquid is accelerated after introduction of the cold liquefied gas, in particular by passing the mixture through a Venturi nozzle. Due to the direct entry of the refrigerant-liquefied gas into the flowing liquid, heat is removed from the liquid by the evaporating gas. The liquid is thus cooled. In a preferred embodiment, the evaporation of the cryogenic liquefied gas is accelerated by the vacuum present in the Venturi nozzle. The resulting gaseous gas initially has a boiling point and is transported further as a gas bubble in the mixing tube. The liquid continues to cool and the vaporized gas continues to heat up. When the freezing temperature of the liquid falls below at least partially frozen liquid is formed, depending on the available cooling energy of the cold-liquefied gas. The frozen liquid is immediately divided again by the gas bubble swarm. This highly turbulent mixing process quickly balances the liquid temperature in both the radial and axial directions. The temperature of the gas and the liquid are equal to each other, wherein after sufficient residence time of the gas in the liquid, there is only a small temperature difference. Optimum utilization of the cold energy stored in the refrigerated liquefied gas is thus achieved. Upon exiting the mixing tube is thus a three-phase mixture of frozen liquid, liquid and gas before.

Preferably, liquid nitrogen is used as the cold-liquefied gas. Since the cooled liquid is also directed to other processes, Liquid nitrogen is preferably used due to its inert properties.

Preferably, the liquid flows at a rate of 0.1 m / s [meter / second] to 5 m / s, preferably from 0.4 m / s to 2 m / s in the mixing tube. Experiments have shown that with such a flow rate of the liquid, optimum use of the refrigerated liquefied gas can be achieved. In operation, the liquid is constantly conveyed through the mixing tube, which can be realized, for example, by a pump.

Furthermore, it is advantageous if the cryogenic liquefied gas is introduced into the flowing liquid at a rate of 1 m / s to 50 m / s, preferably 5 m / s to 20 m / s. The velocity of the cold-liquefied gas is determined at the point where the cold-liquefied gas is introduced into the flowing liquid. It has been found that, with this flow velocity of the cryogenic liquefied gas, in particular in combination with the flow velocity of the liquid, in particular downstream of the optionally formed venturi nozzle, optimal mixing of cryogenic liquefied gas and liquid and thus ideal cooling of the liquid is achieved.

To improve the effectiveness, it is particularly advantageous if the liquid is pre-cooled. In particular, it is preferred that the liquid is cooled to just above its freezing point. In the case of water, the water is thus pre-cooled to 0 ° C. A pre-cooling can be done in particular with a device and a method from DE 10 2007 016 712 AI. By pre-cooling the liquid to its freezing point, the liquid freezes as soon as it comes into contact with the cold-liquefied gas, thus achieving increased effectiveness or an even greater frozen fraction is achieved in the liquid.

It is particularly advantageous if the resulting amount of frozen liquid is regulated via the introduced quantity of the cold-liquefied gas. To determine the required amount of refrigerated liquefied gas, it is necessary to determine both the flow rate of the liquid and its temperatures prior to introduction into the mixing tube. The amount of liquified nitrogen introduced for cooling, e.g. of water is then calculated by the formula m, ün = k × m, water χ ΔΤ / Cl. In this case, k is an empirically determined correction factor which, above all, takes into account the wall cooling losses of the mixing tube, ie the water

Amount of water in kg / h [kilograms / hour], ΔΤ the temperature difference in water in ° C and Cl (P, T) = 83.3. This is based on a pressure of the liquid nitrogen of 5 bar in a nitrogen tank. If the liquid, eg water, is cooled below its freezing point, the amount of cold-liquefied gas introduced, e.g. For example, nitrogen, with the formula m, ün = kx [rn water χ ΔΤ / Cl + X ice xm, water x C2], where X _Qs, the proportion of the liquid to be frozen in the liquid and C2, the cold energy of the cold liquefied gas is taken into account for the conversion of liquid into frozen liquid, wherein C2 is at nitrogen as the cryogenic liquefied gas and water as the liquid is 1.049 at a pressure of 5 bar in the nitrogen tank. It is thus possible to easily determine the ice content in the liquid by the added amount of cold liquefied gas. Preferably, the amount of frozen liquid is controlled to a level between 0% and 70% of the liquid. A high proportion of frozen liquid in the suspension enables a high cooling capacity to be achieved.

In order to prevent after the termination of the introduction of the cold liquefied gas that the liquid passes into the feed of the cold liquefied gas, advantageously after completion of the introduction of the cold-liquefied gas, gaseous gas is introduced through the mixing tube into the flowing liquid.

According to a further advantageous development, the cold-liquefied gas is introduced via a heat-insulated injection nozzle.

The formation of a heat-insulated injection nozzle, in particular a vacuum-insulated injection nozzle prevents the formation of an ice sheet around the injection nozzle, which can lead to the blocking of the mixing tube. Alternatively or additionally, an injection nozzle which is heated at least in part, for example an electrically heated injection nozzle for introducing the cold-liquefied gas, may be formed in order to prevent the formation of an ice sheet around the injection nozzle. By "heated" is meant in this context, in particular, that additional heat energy is introduced into the system from the outside. This can be done in addition to an electric heating by a heat medium as a heat exchanger, which is passed in thermal contact with the injector at this. The thermal insulation can, for example, by a vacuum-insulated jacket or by a foam insulation or by the use of a heat-insulating material, eg. As PTFE, for the injection nozzle itself. According to a further advantageous embodiment, the liquid is guided so that it initially is in thermal contact with a region of the mixing tube, in which the cold liquefied gas is introduced into the mixing tube and then flows into the mixing tube.

This on the one hand ensures that the liquid is pre-cooled before it flows into the mixing tube, on the other hand, the area in which the cold-liquefied gas is introduced into the mixing tube, heated. Thus, the formation of an ice sheet around the injection nozzle can be avoided. In particular, such a configuration is selected in which the liquid initially flows around in particular the region of the mixing tube which lies in the flow shadow of the injection nozzle, since the formation of ice regularly begins there. Flow shadow is understood in particular to be the area behind the opening of the injection nozzle. An embodiment is preferred in which the liquid initially flows in a region which lies fluidically upstream of the injection nozzle and then flows in the direction of introduction of the cold liquefied gas. When a Venturi nozzle is formed downstream of the injection nozzle, evaporation of the gas due to contact of the liquefied gas with the liquid and heat exchange with the liquid are intensified by the negative pressure in the venturi, simultaneously accelerating the liquid / gas mixture and thereby the turbulent matter - And heat exchange between liquid and gas is improved.

According to an advantageous embodiment of the method according to the invention, the mass flow of at least one of the following components is regulated:

a) the liquid and

b) the refrigerated liquefied gas. After reaching the temperature-controlled ice point of the liquid, the additionally necessary amount of refrigerated liquefied gas, which is determined to produce the desired proportion of ice in the liquid via a process computer and the necessary amount of refrigerated liquefied gas.

In principle, an embodiment of the method is possible in which the mass flow of the liquid and / or the cold-liquefied gas is controlled, whereby a very precise control of the process sequence is possible. For many applications, however, it is sufficient to control the mass flow of the refrigerated liquefied gas. In particular, when the mass flow of the liquid is known or adjusted in order to produce, for example, a certain amount of water ice suspension, the regulation of only the mass flow of the cold liquefied gas is advantageous, since only a single control loop has to be formed.

According to another aspect of the invention, an apparatus for cooling a liquid is also proposed, comprising a mixing tube with at least one liquid inlet and at least one liquid outlet and at least one injection nozzle for introducing a cold-liquefied gas into the mixing tube. The device is particularly suitable for carrying out the method according to the invention.

Advantageously, a Venturi nozzle is formed downstream of the injection nozzle. In operation, this leads to the acceleration of the mixture of liquid, in particular water, and cold-liquefied gas, in particular nitrogen. As a result, the Reynolds number of the mixture is increased, it comes to the formation of a turbulent flow, which leads to a good mixing of the liquid and the gas.

The liquid to be cooled is introduced into the mixing tube through the liquid inlet and reaches the liquid outlet via the liquid outlet. ren processes. By the injection nozzle cryogenic liquefied gas can be introduced into the mixing tube so that the liquid at least partially freezes and in particular a three-phase suspension of frozen liquid, liquid and vaporized gas is formed.

In order to achieve uniform mixing of the liquid and the cold-liquefied gas during operation, it is advantageous if the injection nozzle is arranged concentrically in the mixing tube and, more preferably, the velocity is accelerated by a Venturi nozzle. It is particularly advantageous if the cold-liquefied gas is introduced into the mixing tube with the flow direction of the liquid.

It is advantageous if the mixing tube has a mixing length and a mixing tube diameter and the ratio of mixing length to mixing tube diameter is between 50 and 300, preferably between 100 and 150. The mixing length is the distance from the outlet opening of a first injection nozzle in the direction of flow of the liquid to the liquid outlet, from which the liquid reaches further processes. The mixing tube diameter is the inner diameter of the mixing tube, in which the liquid is guided and in which the cold-liquefied gas is introduced. It has been found that with such a ratio optimum mixing of liquid and cryogenic liquefied gas sets and thus a high cooling efficiency is achieved.

Furthermore, it is advantageous if the injection nozzle is arranged in a thermally insulated manner in the mixing tube. The thermal insulation may, for example, by a vacuum-insulated jacket or by a foam insulation or by the use of a heat-insulating material, for. PTFE, for the injection nozzle itself. The thermal insulation prevents frozen liquid in the area of the outlet of the injector. se, in particular in an annular gap between the inlet nozzle and mixing tube, fixed and clogged this.

Furthermore, a freezing of the liquid in this annular gap is prevented by this annular gap is heated from the outside and / or the injection nozzle. For this purpose, it is advantageous if the mixing tube has a double jacket, which forms a gap through which the liquid can be guided. Preferably, the double jacket extends not only in the region of the injection nozzle, but over the entire length of the mixing tube to avoid Eisanbackungen on the inner wall of the mixing tube. During operation, it is thus possible first to guide the liquid to be cooled through the gap, whereby, on the one hand, the liquid is precooled and, on the other hand, the area of the injection nozzle is warmed up, so that a freezing of the liquid in the outlet of the injection nozzle is prevented. The pre-cooled in the gap liquid can be further cooled after passing through the gap and subsequently supplied to the mixing tube again, so that the liquid freezes at least partially by the cryogenic liquefied gas. In order to realize a delivery of the liquid, it is advantageous if a pump is arranged in the liquid line.

Further, it is advantageous if the mixing tube inlet and / or the injection nozzle is associated with a control valve and optionally a quantity measurement. Thus, the flow rates of both the liquid and the cold liquefied gas can be adjusted via the control valve. It is thus possible to adapt to the required conditions.

It is particularly advantageous if the device comprises a control unit. The device can also have temperature sensors and / or flow rate sensors in the feed line of the liquid and / or the cold-liquefied gas for supplying signals to the control unit. The control unit can be controlled via controllable valves and If necessary, quantity measurements or via pumps control the flow rate of the liquid and of the cold-liquefied gas in such a way that a predeterminable cooling capacity is provided. According to an advantageous embodiment, the device is designed so that the liquid can flow through the gap in the region in which the injection nozzle is formed.

This easily allows heating of the injector to prevent the formation of ice blocking while the liquid is thus pre-cooled.

According to one aspect of the invention, the use of the method according to the invention and / or the device according to the invention for cooling fresh concrete is proposed.

The details and advantages disclosed for the method according to the invention can be transferred and applied to the device according to the invention and vice versa.

The invention and the technical environment will be explained by way of example with reference to the figures. It should be noted that the figures show particularly preferred embodiments of the invention, but this is not limited thereto. Show it:

1 shows a first embodiment of the device according to the invention;

Fig. 2: the arrangement of an embodiment of the invention

Device in a cooling device; Fig. 3 shows a second embodiment of the device according to the invention.

1 shows schematically an embodiment of the device 1 according to the invention, which comprises a mixing tube 2. Centrally in the mixing tube 2, an injection nozzle 5 is arranged concentrically for introducing a cold liquefied gas. The mixing tube 2 has a double jacket 8, which forms a gap 9. Via a first mixing tube inlet 3, liquid can be introduced into the gap 9, which leaves the gap 9 via a first mixing tube outlet 4. The mixing tube 2 has a second mixing tube inlet 18, through which the liquid can be introduced into the central lumen of the mixing tube 2 In a Venturi nozzle 19, the centric cold-liquefied gas jet is accelerated along with the concentric liquid jet and intensively mixed, whereby the cold-liquefied by the pressure reduction Gas evaporates and the latent heat passes to the surrounding liquid. From the central lumen of the mixing tube 2, the liquid leaves the mixing tube 2 through a second mixing tube outlet 20. The mixing tube 2 has a mixing length 6 which is measured from the outlet of the injection nozzle 5 to the second mixing tube outlet 19. The mixing tube also has an inner mixing tube diameter 7.

In operation, liquid, preferably water, is introduced through the first mixing tube inlet into the gap 9, where the liquid firstly heats the mixing tube 2 and the injection nozzle 5 to prevent freezing of the outlet of the injection nozzle 5 and is precooled. In particular, the liquid is guided in the gap 9 in such a way that first the area of the flow shadow of the injection nozzle 5 is flowed around and then the liquid moves downstream with respect to the introduced cold-liquefied gas. After exiting the first mixing tube outlet 4, the liquid is guided via the second mixing tube inlet 18 into the central lumen of the mixing tube 2. About the Injection nozzle 5 refrigerant-liquefied gas is introduced into the central lumen of the mixing tube 2. The cold liquefied gas begins to boil on contact with the liquid and cools it. When falling below the freezing point of the liquid, solid liquid is formed, which is broken by the swarm of bubbles of the now evaporated previously refrigerated liquefied gas. It thus forms a kind of slush. Due to the highly turbulent flow optimum mixing of the cold liquefied gas with the liquid and optimal heat transfer is achieved. The suspension of liquid, frozen liquid and vaporized previously cooled liquefied gas is fed via the second mixing tube outlet 20 to a further processing process, in particular a cooling of fresh concrete.

FIG. 2 shows schematically an arrangement of the embodiment of the inventive device 1 according to FIG. 1 with a pre-cooling device. The device 1 according to the invention corresponds to the embodiment of the device according to the invention shown in FIG. 1 and is therefore described only in the differing features. The pre-cooler 24 comprises an insulated container 12 in which the liquid can be temporarily stored and pre-cooled. The pre-cooling is carried out by introducing a cold liquefied gas or a cold gas via nozzles 17. The gas can be discharged via a packing 16 again. In addition, refrigerated liquefied gas lines are shown, via which both the nozzles 17 and the injection nozzle 5 are supplied with cold-liquefied gas. In the cold liquefied gas-carrying lines 20, a heat exchanger 15 is arranged, which at least partially evaporates the cryogenic liquefied gas, which is used for flushing and keeping the injectors 15, 17 free. In addition, control valves 10 and flow rate sensors 13 are arranged in the lines 17 carrying refrigerated liquefied gas. In addition, liquid lines 21 are shown, through which the liquid is passed. In the liquid line 21 is also a pump 14, in particular a rotary number-controlled pump. The liquid lines 21 are also assigned flow rate sensors 13. The temperature of the liquid in the insulated container 12 is measured by a temperature sensor 23. The flow rate sensors 13, the controllable valves 10 and the temperature sensor 23 are connected via signal lines 22 to a control unit 11.

In operation, the slightly pre-cooled in the columns 9 of the mixing tube 2 liquid is fed to the insulated container 12. The liquid is further cooled in the insulated container 12 by introducing a cold-liquefied gas or a cold gas, and kept at a temperature near the freezing point, if possible. About the pump 14, the liquid via the second Mischr ear einlas s 18 fed to the mixing tube 2. The liquid is cooled by introducing a cold-liquefied gas via the injection nozzle 5 and freezes at least in part. The resulting suspension of liquid, frozen liquid and evaporated previously cold liquefied gas is fed to a further process via the second mixing tube outlet 19. The flow rates of the liquid and the cryogenic liquefied gas and the temperature of the liquid are controlled by means of the control unit 11, so that the predefinable process parameters of the suspension are achieved.

3 schematically shows a second embodiment of the device 1 according to the invention. Identical elements in comparison with the first embodiment are provided with the same reference numerals. Attention is drawn to the description of the figures of the first embodiment, in particular the description of the figures relating to FIG. 1, since only the differences from the first embodiment are to be explained here. Fig. 3 shows a Venturi nozzle 25 which is formed downstream of the injection nozzle 5 with respect to the flow direction of the mixture of liquid and gas. In operation, this Venturi nozzle 25 accelerates the flow of the mixture, this is achieved by increasing the Reynolds number at least in some areas turbulent, so that there is an improved mixing between liquid and gas. This significantly improves the uniformity of the cooling of the liquid. The following is a comparative example, the use of a water-ice mixture with about 30% of ice content, which is needed for the production of concrete described. This method is used especially in the summer for the production of chilled quality concrete, for example, in the construction of dams, bridges, or so-called "white tubs" to avoid stress cracks in the setting concrete.

Comparative Example 1

 Fresh concrete composition and temperature of the starting materials

Preparation of a water / ice mixture by direct injection of liquid nitrogen, tank pressure 5 bar

Cooling water quantity [m ³ / h] 7.2

 Cooling capacity [kW] 257

 LIN quantity [kg / h] 2.651

Specific LIN consumption kg / ^° C * m ³ 7.6

Fresh concrete temperature after cooling [ ^° C] 20.1

Temperature difference [ ^° C] 5.9

In the direct cooling of 240 kg of water from 12 C to 0 ^° C and formation of about 30% ice content by blowing liquid nitrogen was at the available mixing time of about 2 minutes, a cooling capacity of about 257 kW, corresponding to a LIN quantity of 2,651 kg / h needed. This corresponds to a specific LIN consumption of approx. 7.6 kg _LIN / C * m ³ _{B ton} . The fresh concrete temperature was cooled from approx. 26 ^° C to 20,1 ^° C.

The following describes the use of a water / ice mixture of 0 ^° C and an ice content of 60% for the cooling of fresh concrete.

Comparative Example 2:

 Fresh concrete composition and temperature of the starting materials

Preparation of a water / ice mixture by direct injection of liquid nitrogen, tank pressure 5 bar

By pre-cooling the water to 0 ^° C in a separate mixing tank and subsequent ice production in the mixing tube of a water / ice suspension was prepared with an ice content of about 50% and thus reached a temperature drop in fresh concrete from 26 to 15.1 ^° C. In order to realize this temperature difference, the existing cooling capacity in the water tank of 111 KW had to be increased by an additional 367 kW, corresponding to a total amount of liquid nitrogen of 4017 kg / h, which could be realized without problems with the cooling method according to the invention. The specific LIN consumption is approx. 7.9 The present invention makes it possible in a simple manner to prepare a water / ice suspension which has a high ice content. With the present invention it is also possible to adapt the cooling capacity to short-term peak cooling powers required by further processes. In addition, there is a very efficient transfer of energy from the liquid to the cryogenic liquefied gas.

LIST OF REFERENCE NUMBERS

1 device

 2 mixing tube

 3 mixing tube inlet

 4 mixing tube outlet

 5 injection nozzle

 6 mixed length

 7 mixing tube diameter

 8 double jacket

 9 gap

 10 adjustable valve

 11 control unit

 12 insulated containers

 13 flow rate sensor

 14 pump

 15 heat exchangers

 16 filling bodies

 17 nozzles

 18 second mixing tube inlet

 19 second mixing tube outlet

 20 refrigerated liquefied gas leading line

21 fluid line

 22 signal line

 23 temperature sensor

 24 pre-cooling device

 25 Venturi nozzle

Claims

claims

A method of cooling a liquid, wherein a cryogenic liquefied gas in a mixing tube (2) is introduced into the liquid flowing through the mixing tube (2), wherein at least a part of the liquid freezes.

The method of claim 1, wherein the liquid flows at a rate of 0.4 m / s to 2 m / s in the mixing tube (2).

A method according to claim 1 or 2, wherein the cryogenic liquefied gas is introduced at a rate of 5 m / s to 20 m / s into the passing liquid.

Method according to one of the preceding claims, in which the cold liquefied gas is introduced via a thermally insulated injection nozzle (5).

Method according to one of the preceding claims, wherein the cryogenic liquefied gas is introduced via an injection nozzle (5) which is heated.

Method according to one of the preceding claims, in which the mixture of refrigerated liquefied gas and liquid is accelerated after introduction of the cold liquefied gas.

Method according to one of the preceding claims, in which the mass flow of at least one of the following components is controlled:

a) the liquid and / or

b) the refrigerated liquefied gas.

8. The method according to any one of the preceding claims, wherein the liquid is guided so that it initially in thermal contact with a portion of the mixing tube (2), in which the cold-liquefied gas is introduced into the mixing tube (2) and then into the Mixing tube (2) flows.

9. Apparatus (1) for cooling a liquid comprising a mixing tube (2) having at least one liquid inlet (3; 18) and at least one liquid outlet (4; 20) and at least one injection nozzle (5) for introducing a cold liquefied gas into the liquid Mixing tube (2).

10. Device (1) according to claim 9, wherein downstream of the injection nozzle, a venturi nozzle (25) is formed.

11. Device (1) according to claim 9 or 10, wherein the injection nozzle (5) concentrically in the mixing tube (2) and optionally the Venturi nozzle (25) is arranged.

12. Device (1) according to claim 9 to 11, wherein the mixing tube (2) has a mixing length (6) and a mixing tube diameter (7) and the ratio of mixing length (6) and mixing tube diameter (7) is between 100 and 150.

13. Device (1) according to one of claims 9 to 12, wherein the injection nozzle (5) thermally insulated in the mixing tube (2) is arranged.

14. Device (1) according to any one of claims 9 to 13, wherein the mixing tube (2) has a double jacket (8) which forms a gap (9) through which the liquid can be guided.

15. Device (1) according to claim 14, wherein the mixing tube (8) is designed so that the liquid can flow through the gap (9) in the region in which the injection nozzle (5) is formed.

16. Device according to one of claims 9 to 15, wherein the injection nozzle (5) is heatable.