WO2000053983A1

WO2000053983A1 - Device and method for vacuum-drying

Info

Publication number: WO2000053983A1
Application number: PCT/EP2000/002111
Authority: WO
Inventors: Heinz-Bernhard GRÖNINGER
Original assignee: Fraunhofer-Gesellschaft zur Förderung der angewandten Forschung e.V.
Priority date: 1999-03-11
Filing date: 2000-03-10
Publication date: 2000-09-14
Also published as: EP1080333B1; ATE440253T1; DE50015717D1; EP1080333A1; DE19910723A1

Abstract

The invention relates to a device and a method for vacuum drying, according to which, in a first step, the object to be dried is heated and pre-dried in a vacuum chamber (1), which can be closed such that it is air-tight, by means of convection heat assisted by circulating air. In a second step a vacuum is generated in the chamber and in a third step a gaseous substance is fed through said chamber. The invention notably relates to such a method for vacuum drying according to which drying can be carried out by automatic control involving the selection of suitable control quantities.

Description

Device and method for vacuum drying

The present invention relates to a device and a method for vacuum drying industrial articles such as mechanical or electronic components, workpieces, etc. In particular, the present invention relates to such a device and method that can operate according to a self-controlling principle.

Drying processes are known in many variants.

Circulating air drying is a technically very simple but energy-intensive process. Other drying processes are, for example, infrared drying, vacuum drying or clothing drying. Depending on the specific application, one or the other method is used in practice.

The problem with the known methods is the long and energy-intensive drying times which, depending on the type of material and the nature of the object to be dried, can lead to further problems. Complicated structures such as blind holes, undercuts, blowholes and capillaries make drying particularly difficult.

For example, corrosion-sensitive materials such as steel materials are dried, e.g. after treatment or cleaning in an aqueous medium, the drying time should be short to minimize the risk of surface corrosion due to water adhering to it. In particular, complicated, angled structures, which are difficult to dry or dry, have a disadvantageous effect on the drying time.

It has also been shown that drying processes can be affected by common environmental conditions, e.g.

REQUIREMENTS KDP € Impurities such as dust particles can be entered in the drying system, which adhere to the items to be dried and as a result of further processing such. B. a subsequent coating, or adversely affect their usability.

A number of approaches have been proposed to further develop the known drying methods to solve the problems mentioned above.

So vacuum is applied to shorten the drying time, which lowers the boiling point of the solvent or cleaning agent adhering to the article.

According to a further solution, drying is achieved by an upstream convection heater in a hot aqueous bath. It is also known to support the actual drying by an upstream nitrogen blow-off.

It has also been proposed to eliminate or at least reduce the problem of icing that occurs in vacuum drying due to the loss of energy by preheating the articles.

EP-A-0 539 607 describes a device in which the article to be dried is preheated by means of hot air and then dried in vacuo. In order to be able to increase the throughput even with longer drying times, several vacuum chambers can be connected in parallel.

The results achieved with the known methods are, however, not sufficient for many industry-relevant applications.

In particular, there is a lack of a method that can solve the various problems that can arise during drying in a holistic manner. DE 30 39 923 describes a device for the generation and maintenance of a residual gas atmosphere in the vacuum area which is largely free of interfering gases and which contains a vacuum chamber, the vacuum chamber being connected to an adsorption trap and the residual gas being withdrawn from the vacuum chamber and circulating via the Adsorption trap is returned to the chamber. Vacuum drying of the type described above is not provided, however.

It was an object of the invention to provide a method and a device which, in addition to short drying times and low energy consumption, can ensure reproducible and high drying quality even in the case of articles of complicated construction and sensitive to corrosion.

This object is achieved by a device for vacuum drying, which contains an airtight sealable vacuum chamber, a heating device, openings for introducing and discharging gaseous substances and a gas supply line, the device being connectable to a vacuum pump and the heating device being arranged within the vacuum chamber.

The present invention further relates to a multi-stage process for drying, the article to be dried being heated in the vacuum chamber in a first stage by means of convection heat and simultaneously pre-dried, then vacuum applied in a second stage and a gaseous substance being passed through the chamber in a third stage becomes.

According to a particularly preferred embodiment, the multi-stage drying method according to the invention is carried out under program control via the measurement and determination of control variables. The course and duration of the individual stages are controlled by measuring relevant control variables and comparing the measured control variables with specified target values.

This control enables an optimal and reproducible drying result to be obtained for the individual drying stages. Completely automated drying is also possible via self-control.

The present invention is also extremely suitable for drying bulk goods. For this purpose, a container for receiving the bulk material to be dried can be provided within the vacuum chamber. The container can be provided with a drive which sets the container in motion and thus also the bulk material in the container, which promotes drying. The container is preferably designed as a drum.

The invention is explained in more detail below with reference to a figure using a preferred embodiment.

It shows

Figure 1 schematically shows a longitudinal section through a preferred

Arrangement of the device according to the invention;

FIG. 2 shows the configuration of a device according to the invention for drying bulk goods.

1 shows a longitudinal section through a device for vacuum drying preferred according to the invention, the essential components of which are a chamber 1 for receiving the article or articles to be dried, a closure le for airtight sealing of the chamber 1, a heating device 2, 3, openings 4, 5 for introducing and discharging a gaseous substance, a gas feed line 6 and a connection 7 for a vacuum pump 9.

The heating device is used to generate convection heat and can preferably consist of one or more radiant heaters. The preferred device shown in FIG. 1 has, for example, two opposite radiant heaters 2, 3. Other heating devices for generating convection heat are also conceivable.

As an alternative or in addition to the heating device 2, 3 mounted internally in the chamber 1, an external heating device can be provided. Here, the gaseous substance supplied via the opening 4, such as circulating air, can be heated via a heating device connected upstream of this opening 4, and the heating of the article or articles to be tumbled in the chamber 1 takes place via the externally heated gaseous substance. The chamber 1 has openings 4, 5 for introducing and discharging gaseous substances, preferably air, for generating circulating air. The openings are made so that an optimal flow through the chamber or flow around the article or articles is achieved. For example, they can be provided offset in height in opposite wall sides as in the example shown in FIG. 1, reference numeral 4 denoting the opening for introduction and reference numeral 5 denoting the opening for draining.

A plurality of supply openings and / or discharge openings can also be provided.

As shown in FIG. 1, the feed line and the discharge line can be connected to one another.

The regulation of the flow velocity of the circulating air and thus the amount of air supplied takes place via suitable means for regulating the gas supply and discharge 10, 11 such as fans, which can preferably be frequency-controlled, or also suitable pumps. In addition, valves, reusable taps or the like can be used to regulate the gas supply and discharge, e.g. in Figure 1, the valves 12, 13 may be provided.

For the supply of fresh air or removal of moisture-laden recirculating air, appropriate devices such as e.g. Throttle valves 14, 15 may be provided.

For the self-control preferred according to the invention, these devices can work in a controlled manner via measuring points.

The air preferably passes through a filter device (not shown) before being introduced into the chamber in order to remove impurities such as dust particles etc. and to avoid contamination of the chamber. A heating device and / or a drying device can also be provided outside the chamber 1 in the duct system for the circulating air, in order to preheat the air before it is introduced into the chamber and / or to reduce its moisture content. For example, a condenser for drying the moisture-laden circulating air, which leaves the chamber 1 via the opening 5, can be provided in the circulating air duct system. In this case, the throttle valves 14, 15 can be dispensed with.

The capacitor is preferably located on the output side in the line system.

In principle, any gas such as ambient air, an inert gas or mixtures thereof can be used for circulating air drying. Ambient air is preferably used.

The chamber 1 can be connected to a vacuum pump 9. In the device shown in FIG. 1, the chamber is connected to the vacuum pump 9 via lines 22a and 7, the line 22a being connected to measuring points 23 and 24 at the same time. In Figure 1, access to line 22a is controllable via a valve 16, the vacuum pump 9 being a controllable valve 17, e.g. a butterfly valve, can be upstream.

The device according to the invention also has a gas feed line 6, via which any other gas, preferably an inert gas, can be fed. Via the gas supply line 6, e.g. gas is fed in for the third stage.

As shown in FIG. 1, the gas feed line 6 can be connected to reservoirs 8 for different gases, so that, depending on the application, the type of gas fed in can be changed or a mixture of any composition can be introduced. To control the gas supply, valves, multi-way valves or the like can be provided in the gas supply line 6 itself or in the supply lines to the individual reservoirs.

So-called flow controllers are preferred for this purpose, which allow a regulated gas supply.

An inert gas such as nitrogen or argon or mixtures thereof is preferably added for the third stage in order to prevent corrosion. Depending on the application, air or oxygen etc. can also be introduced.

Here, too, a heating device can be provided to preheat the gas and / or, if necessary, a drying device can be provided to promote drying.

Optionally, the device according to the invention can be equipped with suitable further devices as required, e.g. with ventilation 18, cooling 19 and / or a drain line 30 which e.g. can be switched on via valves 31, 32 and 33.

FIG. 2 shows a section of a device according to the invention as shown in FIG. 1, a container - here a drum 40 - being arranged in the vacuum chamber. This configuration is particularly suitable for drying bulk material, the container or drum 40 being used to hold the bulk material. The drum 40 is rotated or rotated via a drive 41, the bulk material therein being freed of moisture efficiently and quickly.

According to the method according to the invention, heat is applied to the article or articles to be dried with convection heat in a first stage. This is preferably done by means of an energy-intensive but short radiant heat supported by circulating air drying by means of the heating device 2, 3 and / or an external heating device for heating the circulating air. air before entering chamber 1. Here the article absorbs thermal energy to counteract icing when a vacuum is applied. At the same time, pre-drying takes place by removing a first large part of the surface moisture.

Following the application of heat, a vacuum is applied in a second stage or the pressure in chamber 1 is reduced. A large part of the surface moisture has already been removed at this point.

Simultaneously with the pressure reduction and / or afterwards after the desired pressure reduction has been achieved, gas is passed through the chamber to promote drying (third stage). In this case, an inert gas is preferably used in order to simultaneously generate a protective atmosphere.

The vacuum or a desired pressure can be maintained via appropriate regulation of the necessary control variables.

The vacuum drying method according to the invention is preferably carried out independently or program-controlled on the basis of control variables.

Here, for the individual stages, i.e. one or more suitable control variables are selected for the individual procedural measures such as heat application, pressure reduction and gas introduction, and the course of drying in the individual stages is monitored and controlled by determining the actual values of the respectively selected control variables and comparing them with predetermined target values.

The actual values of the individual control variables can be measured via measuring points or probes 23, 24, 25, which can be installed in the chamber 1 itself or connected to it, the measuring points or probes in turn being connected to control devices. 1 shows temperature sensors 20, 21, which are provided in the chamber, and outside the chamber, lines 22 a, b, c, which connect the chamber with measuring devices and control devices for the individual control variables such as the pressure, the moisture content, and the temperature etc. connects. One or more measuring probes 25 for the moisture content of the air can also be provided in the line system for the circulating air.

Depending on the deviations of the measured actual values from the target values, the control variables and / or the duration of the individual stages can be changed, so that a uniformly optimal drying result can be achieved even for articles of complicated construction and difficult to dry.

Control variables can be the heat, the humidity, the temperature, the position of the

Valve flaps, the frequency of the fans and the pump output;

Pressure reduction the pressure, supported by the moisture measurement, the temperature, position of the valve flaps;

Gas or inert gas supply, the amount of gas supplied, the pressure, the temperature, the valve position and the moisture measurement, control of the flow controller.

The control parameters, or in other words, the recording and fulfillment of all important parameters, determine the optimal termination of the respective drying step over the entire process. Even difficult to access areas can be dried quickly and efficiently using this system.

Parameters to be set preferably are such that drying takes place at a temperature in a range from 50 ° C. to 150 ° C. Preferred gases are nitrogen or argon. The preferred flow rate (flow rate) can be from 0 to 50,000 sccm with a chamber volume of 1 m ³ , with a vacuum between 10 and 100 mbar.

According to the invention, drying takes place in a closed drying system, which prevents contaminants from being carried in from the environment. The dried objects therefore meet a high standard of purity, so that subsequent coating processes can also be carried out without any problems. In addition, the method according to the invention is ecological and economical. It is particularly suitable for components that require a high degree of purity, such as. B. for components from the fields of medicine, aerospace or the glass industry as well as for drying bulk goods.

Reference list

Vacuum chamber a closure, 3 heating devices

Opening for introducing a gaseous substance

Opening for the discharge of a gaseous substance

Gas supply

Connection to a vacuum pump

Gas reservoir

Vacuum pump

0 Fan 1 Fan 2 Valve 3 Valve 4 Throttle valve for circulating air supply 5 Throttle valve for circulating air discharge 6 Valve 7 adjustable valve 8 Ventilation 9 Cooling

0 temperature sensor 1 temperature sensor 2a, b, c connecting lines to measuring points of the control variables 3 measuring point for control variables 4 measuring point for control variables 5 measuring probe for humidity Outflow

Drain valve

Ventilation valve

Cooling valve

Bulk containers

drive

Claims

claims

1. Device for vacuum drying containing an airtight sealable vacuum chamber (1), openings for introducing and discharging gaseous substances (4, 5), a gas supply line (6), the device being connectable to a vacuum pump (9), characterized in that the device arranged inside the vacuum chamber (1) contains a heating device (2, 3).

2. Device according to claim 2, characterized in that the device has at least one measuring point (23, 24, 25) for determining control variables which are connected to the vacuum chamber (1) and / or are arranged within the vacuum chamber (1) .

3. Device according to claim 2, characterized in that at least one temperature sensor (20, 21) is arranged within the vacuum chamber.

4. Device according to one of claims 1 to 3, characterized in that means for regulating the gas supply and discharge (10, 11) are provided.

5. The device according to claim 4, characterized in that the means for regulating the gas supply and discharge (10, 1 1) are selected from a fan or a pump.

6. The device according to claim 4 or 5, characterized in that additional valves (12, 13) are provided for regulating the gas supply and discharge.

7. Device according to one of the preceding claims, characterized in that two opposite radiant heaters (2, 3) are provided as the heating device in the chamber (1).

8. Device according to one of claims 1 to 6, characterized in that the heating device is provided on the input side to the opening 4 outside the chamber (1).

9. Device according to one of claims 1 to 8, characterized in that a container (40) is arranged in the vacuum chamber (1).

10. The device according to claim 9, characterized in that the container (40) is designed as a drum, and can be rotated via a drive (41).

11. Process for vacuum drying, characterized in that the object to be dried is heated and pre-dried in a first stage by means of convection heat in an airtight sealable vacuum chamber (1) by means of convection heat, then vacuum is applied to the chamber in a second stage and in a third stage, a gaseous substance is passed through the chamber.

12. The method according to claim 11, characterized in that the drying takes place via a selection and determination of control variables under self-control.

13. The method according to claim 11, characterized in that the control takes place via at least one control variable selected under the humidity, temperature, pressure, gas flow for circulating air drying and flow controller.

14. The method according to any one of claims 11 to 13, characterized in that the gas introduced in the first and third stages is ambient air and / or an inert gas.

15. The method according to claim 14, characterized in that ambient air is used for circulating air drying in the first stage and an inert gas is used as gas in the third stage.

16. The method according to any one of claims 14 or 15, characterized in that the gas for the first and / or third stage is introduced preheated into the chamber (1).

17. The method according to any one of claims 12 to 16, characterized in that a gas or gas mixture according to the third stage is added to the chamber (1) simultaneously with the pressure reduction in the second stage.

18. The method according to any one of claims 12 to 17, characterized in that bulk material is dried.