TR2021018814T6 - Drying device and method for drying a compressed gas - Google Patents

Abstract

Drying device comprising at least two containers (2) with renewable desiccant (3) and an adjustable valve system (4) for drying the compressed gas, where one vessel (2) can dry the compressed gas while the other vessel (2) is renewed, where the valve system ( 4), each of the containers (2) can dry the gas in turn, the device being characterized in the drying device (1) to feed a regeneration gas flowing from an outlet (8) for the dried gas to the valve system (4), and inside a heating means (11). having a regeneration pipe (10), wherein said return pipe (17) in the drying device (1) extends from the valve system (4) to an inlet pipe (13) connected to said inlet (7), in order to return the regeneration gas to an inlet (7). there is a return pipe (17) mounted on the venturi ejector (18) to which it is connected, and regulation means are provided for regulating the gas flow passing through the venturi ejector (18).

Description

specification Drying device and method for drying a compressed gas The present invention relates to a drying device for drying a compressed gas.

In particular, the invention provides an inlet for the compressed gas to be dried and an inlet for the dried compressed gas. pertains to drying devices with an outlet, wherein the drying device is a renewable desiccant at least two vessels containing said inlet and outlet, and an adjustable valve system connecting said vessels where the adjustable valve system allows at least one container to dry the compressed gas while the other container will be renewed and by the arrangement of the valt` system, each of the containers is in turn compressed gas It is configured to dry.

Renewable desiccant is a desiccant capable of absorbing moisture from a gas by adsorption and when saturated with moisture means a dryer that can be dried by sending regeneration gas through it. This is the same name Also called regeneration of the dryer. Typically, the regeneration gas is a hot gas.

Although the adsorption principle is mentioned here, the invention also refers to the absorption principle. applicable.

When a container is sanded, it removes moisture from the compressed gas to be sanded so that the dryer becomes saturated.

This means that it will receive no or very little additional moisture.

This vessel is then regenerated, where typically a hot gas, eg hot air, is through is directed. This hot gas will take moisture from the dryer and thus renew it.

Then the container, optionally, to dry the compressed gas before reuse can be cooled.

Some of the dried compressed gas is used to regenerate a vessel. configured devices are already known.

After being used for regeneration purposes, the regeneration gas is either blown or to be dried. recombined with the compressed gas.

The advantage of recovering the regeneration gas is that no loss of compressed gas occurs Although the regeneration gas can be recombined with the compressed gas to be dried it should be ensured.

In fact, the regeneration will trigger a pressure drop such that the regeneration gas will be dried. compressed regeneration gas to be dried, which will be at a slightly lower pressure than the compressed gas An external force will be needed to recombine with the gas.

To recombine the regeneration gas with the compressed gas to be dried, the compressed gas to be dried A venturi ejector can be used which will create a low pressure as the gas flows through it. this is low Under the influence of pressure, the regeneration gas can be absorbed as it is by the venturi ejector and thus It can be recombined with the compressed gas to be dried.

A relatively large pressure drop can occur in this type of venturi ejector. is a disadvantage.

The object of the present invention is to provide a solution to at least one of the above-mentioned and for other disadvantages. is to provide.

To this end, the invention relates to a drying device for drying compressed gas and said drying An inlet for the compressed gas to be dried and an outlet for the dried compressed gas. wherein the drying device consists of at least two containers containing a renewable desiccant and a first valve block and a second valve connecting said inlet to said outlets, respectively includes an adjustable valve system consisting of a block of can dry the compressed gas, while the other container will be renewed and with the arrangement of the valve system, each of the containers will be one is configured to dry the compressed gas in sequence, where in the dryer also, There is a regeneration pipe to feed a coarse regeneration gas being regenerated and the aforementioned the regeneration pipe passes from the dried compressed gas outlet to the second valve block, where Heating medium for regeneration gas is provided in the regeneration pipe, here in the drying device In addition, after the regeneration gas has passed through the regenerating vessel, it is returned to the aforementioned inlet. there is a return pipe for turning it and said return pipe is from the first valve block, extends to an inlet pipe connected to said inlet for the compressed gas to be dried, where the inlet a venturi ejector is mounted on the pipe, the so-called return pipe is connected to it and the venturi regulating device for regulating the flow of compressed gas to be dried through its ejector has been provided.

This means that with the flow regulation through the venturi ejector, the pressure drop and the associated energy loss provides the advantage of being editable. Indeed, by reducing the flux through the venturi ejector, less regeneration gas will be sucked in and the pressure drop will be lower.

In other words, it is possible to ensure that only sufficient flow passes through the venturi ejector, such that just enough to allow a good regeneration of the greener cabin and more non-regeneration gas is absorbed.

The regulation of the flow through the venturi ejector can be done in different ways.

In a practical application, said regulating means is the flow through which said venturi ejector It is formed by having an adjustable venturi ejector configured so that it can be regulated.

In an alternative practical embodiment, said regulatory device is a valve provided on the venturi ejector. includes a bypass pipe, where a governor is mounted on the bypass pipe.

This valve is, for example, a butterfly valve or throttle valve.

With the valve more or less open, the bypass tube and thus indirectly the venturi ejector the last stream is edited.

The invention also relates to a drying apparatus for drying compressed gas An inlet for the compressed gas to be dried and an outlet for the dried compressed gas. are available. wherein the drying device consists of at least two containers containing a renewable desiccant and consists of a first valve block and a second valve block connecting said outlet to said containers, respectively. It includes an adjustable valve system consisting of an adjustable valve system, where at least one container is compressed. While the gas is drying, the other container is renewed and each of the containers is in turn by arranging the valve system. It is configured to dry the compressed gas, wherein the drying device also There is a regeneration pipe to feed a regeneration gas to the regenerating vessel, and the aforementioned the regeneration pipe passes from the dried compressed gas outlet to the second valve block, where Heating medium for regeneration gas is provided in the regeneration pipe, here in the drying device In addition, after the regeneration gas has passed through the regenerating vessel, it is returned to the aforementioned inlet. there is a return pipe for the return pipe, said return pipe from the first valve block, extends to an inlet pipe connected to said inlet for the compressed gas to be dried, where regeneration A fan is mounted on the pipe and is an adjustable fan.

The aforementioned fan constitutes an alternative to the venturi ejector, that is, the fan has the same function as the venturi ejector. will have.

The invention also provides an inlet for drying the compressed gas and an outlet for the dried compressed gas. relates to a method for compressed gas to be dried using a drying device with An inlet pipe is connected to the inlet, where the drying device is at least one containing a renewable desiccant. two containers and an adjustable valve system connecting said inlet to said outlet respectively said outlet contains, at least one container dries the compressed gas, while the other container is renewed, where the valve system Each of the containers sequentially dries the compressed gas, by arranging the method, the following steps - a regeneration gas by evacuating part of the dried, compressed gas at the outlet providing; - heating this evacuated regeneration gas before it is directed to the vessel being regenerated; - the regeneration gas is returned to the aforementioned inlet pipe after passing through the regenerating vessel rotate; - returning the regeneration gas to the so-called inlet pipe via a venturi ejector, which where the method also includes the step of regulating the flow of regeneration gas sent to the inlet pipe. It is clear that this method has the same advantages as the drying device according to the invention.

A sanding device according to the invention is preferably used to implement the method.

Preferably an adjustable device to regulate the flow of regeneration gas sent to the inlet pipe. venturi ejector is used.

Preferably, some of the compressed gas to be dried is part of the regeneration gas sent to the inlet pipe. It is sent over the venturi ejector through a bypass pipe to regulate its flow, where a valve is installed in said bypass pipe.

The invention also provides an inlet for drying the compressed gas and an outlet for the dried compressed gas. relates to a method for compressed gas to be dried using a drying device with An inlet pipe is connected to the inlet, where the drying device is at least one containing a renewable desiccant. two containers and an adjustable valve system connecting said inlet to said outlet respectively said outlet where the adjustable valve system allows at least one container to dry the compressed gas while the other container to be regenerated, wherein each of the containers is sequentially compressed by the arrangement of the valve system. dries the gas, here the method includes the following steps: - a regeneration gas by evacuating part of the dried, compressed gas at the outlet providing; - heating this evacuated regeneration gas before it is directed to the vessel being regenerated; - the regeneration gas is returned to the aforementioned inlet pipe after passing through the regenerating vessel rotate; - also providing an adjustable fan (23) in the drying device (1), the aforementioned adjustable fan (23) to a regeneration pipe extending from the outlet (8) for dried compressed gas to the aforementioned valve system. (10). includes the step of regulating the flow of the returned regeneration gas.

It is clear that this method also has the same advantages as the drying device according to the invention.

A drying device according to the invention is preferably used to carry out the method.

In order to better illustrate the features of the invention, a method for venting compressed gas according to the invention A few preferred embodiments of the drying device are without limitation in the appended With reference to the figures, they are explained by way of an example below, where: Figure 1 schematically shows a drying device according to the invention; Figure 2 shows an alternative embodiment of Figure 1; Figure 3 shows another practical application of Figure 1; Figure 4 schematically shows another variant of a drying device according to the invention.

Drying device 1 according to the invention for drying the compressed gas shown schematically in Fig. 1, consists essentially of two containers 2 containing a renewable desiccant 3 .

This renewable desiccant 3 is also called desiccant.

It is of course possible to have more than two containers 2.

The drying device 1 further includes a valve system 4 comprising a first valve block 5 and a second valve block 6 .

The first valve block 5 will connect the containers 2 to an inlet 7 for the compressed gas to be dried, the second valve block 6 will connect containers 2 to an outlet 8 for dried compressed gas.

Said valve blocks 5, 6, at least one vessel 2 will always be reconditioned or possibly cooled, other container 2 or other containers 2 different pipes that can be arranged to dry the compressed gas and a system of valves, wherein the arrangement of the valve system 4, each of the containers 2 in turn it will dry the compressed gas.

In this case, each governor block contains 5, 6, four butterfly valves 9 or throttling valves.

In the dryer 1 there is also a gas to provide a regeneration gas to the container 2 being regenerated. There is a regeneration pipe 10.

The dried, compressed gas will be used as the regeneration gas.

For this purpose, the regeneration pipe 10 is routed from the dried compressed gas outlet 8 to the second valve block 6 through which the heating medium 11 is provided for the regeneration gas in the regeneration pipe 10.

In this case, said heating means 11, whose primary section 12a is mounted in the regeneration pipe 10 and secondary section 12b, from the aforementioned inlet 7 to the outlet of a compressor 15 for the compressed gas to be dried. a heat exchanger 12 mounted on an extending inlet pipe 13 .

In this case, the said heater 11 is also an Omemek regeneration pipe 10 mounted on a includes an external heat source 16, which is electrically heated. External heat source 16, 12 down from heat exchanger located in the flow direction.

In the drying device 1 according to the invention, the regeneration gas is also discharged through the container 2 being regenerated. a return pipe 17 for returning it to said inlet 7' via the inlet pipe 13 after it has passed. are available.

For this purpose, the return pipe 17 is drawn from the first valve block 5 for the compressed gas to be dried. extends to said inlet pipe 13, which connects to inlet 7.

A venturi ejector 18 is mounted on the inlet pipe 13 to which the aforementioned return pipe 17 is connected, here the flow of compressed gas to be dried passing through the venturi ejector 18 can be regulated.

In the example shown, this arrangement is due to the fact that a bypass pipe 19 is provided on the venturi ejector 18 it has been possible that a valve 20 is mounted in the bypass pipe 19 here.

This valve 20 allows the flow through the bypass pipe 19 to be regulated and thus from the venturi ejector 18. allows the passing flow to be regulated indirectly as well.

Finally, a cooler 21 is installed in the inlet pipe 13 downstream from the venturi ejector 18. has been made.

The operation of the dryer is very simple and is as follows.

During the l operation of the dryer, it enters the inlet 7 through the hot pressure air cooler 21. will reach.

The cooled compressed gas will be directed into container 2 where it will dry through the first valve block 5.

In figure 1, this is the container on the right 2.

After passing through this container 2, the compressed gas is dried and leaves the drying device l via outlet 8. can.

Some of the dried compressed gas is discharged through the regeneration pipe 10.

This evacuated, dried compressed regeneration gas will be dried through the heat exchanger 12 It is heated by removing heat from the compressed gas.

Consequently, since the compressed gas to be dried is subjected to an initial cooling in the heat exchanger 12, anlan dryer 21 can be applied in a smaller size.

Then hot, dry compressed regeneration gas, which can optionally heat the gas more, The external 1s1 source 10 in the regeneration pipe passes through 16 .

Regeneration pipe 10 now delivers the hot and dry compressed regeneration gas to the second valve block 6 which redirects it through container 2 to be regenerated.

After the regeneration gas has passed through vessel 2, it is heated and saturated with moisture.

Through the return pipe 17, the hot, saturated compressed regeneration gas comes from the compressor 15 It is recombined with the compressed gas to be dried.

Venturi ejector 18 will be used for this.

A vacuum is created when the compressed gas to be dried from the compressor 15 flows through the venturi ejector 18. will create. The size of this gap depends on the flow that flows through it.

The size of the vacuum will determine how much regeneration gas is sucked in and thus how much. will determine when the regeneration gas will be discharged.

By opening the valve 20 of the bypass pipe 19 more or less, the flow of the regeneration gas is also like this. editable.

In this way, the valve 20 is sufficient, but also not more than necessary, out of the 2 containers to be replaced. the regeneration gas can be arranged to flow.

In this way. The pressure drop and associated energy loss on the venturi ejector 18 should be kept as close as possible. can be kept low.

How much regeneration gas is needed and thus 19 valve 20 in the bypass pipe? Some of the things to consider are how much the other tank 2 such as how long it can dry, i.e. how much time there is for regeneration, and/or temperature and relative humidity physical parameters of the regeneration gas and/or 3 of the 2 desiccants in the container to be regenerated. saturation level and/or dew point and the like.

As described above, this regeneration step is carried out until vessel 2 is completely regenerated.

A possible cooling step is also applicable, wherein a cooling gas through said vessel 2 sent.

The containers 2 are then replaced, where the drying container 2 will now be regenerated and the two valves By changing the blog 5, 6 accordingly, the reverse will also happen.

Figure 2 shows a variant according to Figure 1, in which case the external heat source 16 is outside. is left so that some of the butterfly valves 9 in the second valve block 6 are in this case four present Two of the valves are one-way valves 22.

For the rest, the drying device 1 and its operation are similar to the embodiment in Figure 1.

In the example in the figure, some of the butterfly valves 9 or all of the butterfly valves 9 are It can be applied as non-return valves 22 in blog 6 or external heat source is outside. it is clear that it is left.

Figure 3 shows another variant, in which all valves of the second valve block 6 are unidirectional. valves are applied as 22.

In addition, the heat exchanger 12 is left outside and the regeneration gas is only an external heat source 16. is heated using

Of course, the valves in the second valve block 6 are referred to as butterfly valves 9 as shown in Figure 1. possible to operate.

In all examples shown and described, downstream of the inlet tube 13 and the venturi ejector 18 There is a cooler 21 in the direction of. This refrigerant 21 is upstream from the venturi ejector 18 a first refrigerant mounted in the inlet pipe 13 and a second refrigerant mounted in the return pipe 17 It is possible to replace it with a coolant.

In all examples shown and described, flow through venturi ejector 18, bypass 19 with valve 20 can be adjusted via

However, an adjustable venturi ejector through which the flow can be regulated It is also possible to use. This means: the venturi ejector 18 is itself an adjustable valve. similarly adjustable.

Figure 4 shows another variant of the invention.

This means leaving the venturi ejector 18 outside for application and inserting a regeneration tube 17 into it. differs from Figure 1 in that the fan 23 is mounted.

This fan is 23 adjustable, that is, the flow of regeneration gas from the container 2 to be renewed is sufficient, but not the same. means that it can be arranged in such a way that no more than necessary regeneration gas will flow at the time. In other words, this variant provides an alternative for the venturi ejector 18.

In this case, although not essential for the invention, the fan is directed upstream from the heating device 11, ie. The heat exchanger is mounted upstream from the product 12.

To prevent the gas to be dried from inadvertently flowing into the containers 2 via the return pipe 17, the return A non-return valve 24 is also mounted in the pipe 17 .

Finally, I also control my dryer 1, the fan 12 and possibly the adjustable valve system 4 as well. There is a control unit 25 that will.

For the rest, the process is similar to the operation of the applications described above.

Of course, the implementations of Figures 1 to 3 do not require the adjustable venturi ejector 18 and/or bypass. a control unit 25 capable of controlling the valve 20 and/or the adjustable valve system 4 in the pipe 19 may also be included.

In addition, such control unit 25 may also control other components or elements of the drying device 1. possible to control.

The present invention is in no way limited to the applications described by way of example and illustrated in the drawings. but a drying device for drying compressed gas according to the invention, application It can be realized in any form and size without leaving its scope.