DE202023104086U1 - Device for drying plastic granules - Google Patents

Abstract

Device for drying plastic granulate, comprising a drying container (1) which has a removal opening (13) at the end and at least one gas guide channel (2, 3) which is connected to a drying gas source, with means for heating at least one drying gas stream being arranged, characterized that the means for heating the at least one drying gas comprise at least one heat pump (4).

Description

The invention relates to a device for drying plastic granules according to the preamble of claim 1.

Before processing plastic granules, it is essential to dry them. This particularly applies to hygroscopic plastics, such as PA or PBT, which store water molecules in a similar way to a sponge. Moisture in the plastic granules used causes inferior molded parts that do not meet the requirements. Typical defect patterns range from so-called moisture streaks to molecular chain degradation with a corresponding loss of strength.

Different drying processes are used to dry plastic granules. In dry air dryers, dry air is generated in an air drying cartridge in the dryer. The air to be dehumidified is flowed past a so-called molecular sieve in the drying cartridge, which absorbs the water contained in the air. The molecular sieve consists of porous granules (for example a silicate gel), which has a high water absorption capacity. Such an adsorption dryer is, for example, in the DE 20 2017 107 185 U1 described. Here, a drying container is arranged which contains the plastic granules to be dried and which has an upper cylindrical part, which is followed by a lower funnel-shaped part. The drying air is supplied to the plastic granules via a diffuser cone arranged in the middle of the drying container. This so-called adsorption process proves to be very energy-intensive, since heating to 250°C to 350°C is required to reactivate the molecular sieve.

Due to the simple structure, compressed air dryers are also used to dry plastic granules. A valve for pressure and flow rate reduction is connected to a regularly available compressed air connection, to which a process heater is connected, which heats air to drying temperature before it flows through the material container. The following effect is taken advantage of: As the pressure increases, the air's ability to absorb water decreases. When air is compressed, a large part of the water is already separated. If this compressed air is expanded to the ambient pressure, the expanded air has a dew point of approximately -25°C. The dew point is the temperature at which the moisture bound in the air condenses on an object. The lower the dew point of the air, the higher its water absorption capacity. This structure also proves to be very energy-intensive due to the provision of compressed air and the operation of the process heating.

In order to minimize the energy requirements of this device EP 2 399 718 A1 proposed adding a certain amount of ambient air to the drying air, which minimizes the amount of energy-intensive compressed air required. The amount of ambient air that can be supplied is determined using a dew point sensor.

In order to further improve the efficiency of the above devices, in the EP 3 702 710 A1 proposed to introduce the drying gas not centrally via a diffuser cone, as is known in the prior art, but rather from the outside to the inside through a gas guide channel which is arranged at least in some areas radially on the inner wall of the container and cantilevers towards the center axis of the container. By aligning the outlet openings towards the removal opening, the drying gas, preferably preheated relaxed compressed air or air dried by an adsorption dryer, is introduced circumferentially from the outside to the inside into the lower area of the plastic granules in the container, from where it slowly flows upwards through the granules rises and absorbs moisture from the granulate particles around which it flows over a longer period of time, which results in increased moisture removal from the granules.

The above devices for drying plastic granules have proven themselves in practice. Against the background of the still considerable energy requirement of the previously known drying devices, the object of the invention is to further increase the efficiency of such drying devices. According to the invention, this object is achieved by a device with the features of claim 1.

The invention provides a device for drying plastic granules, the efficiency of which is further increased. The fact that the means for heating the at least one drying gas comprises at least one heat pump makes it possible to use the high ambient temperatures in plastic injection molding halls due to the process to minimize the energy required to heat up the at least one drying gas stream.

In a further development of the invention, the heat pump is connected to a cooling fluid reservoir which is connected to at least one injection mold cooling circuit. The tempering of Spritz Casting tools require continuous, energy-intensive cooling of the cooling water heated by the respective injection molding tool, which is then fed back to the injection molding tool for the next cooling process. By connecting a cooling water reservoir that is connected to at least one injection mold cooling circuit, in addition to reducing the energy required to heat up the at least one drying gas stream, a reduction in the energy required to cool the cooling water of the at least one injection mold is also achieved.

In an embodiment of the invention, the heat pump is connected to a cooling fluid reservoir which is connected to the hydraulic cooling system of at least one plastic injection molding machine. The hydraulic system of an injection molding machine is constantly cooled by a cooling system to keep the hydraulic oil in an optimal temperature range. These cooling systems are regularly designed in the form of heat exchangers through which cooling water flows. By connecting the heat pump to the hydraulic cooling system of at least one plastic injection molding machine, the temperature level of the heat pump is further increased, thereby increasing its efficiency. At the same time, this results in a reduction in the energy required to cool the cooling water of the hydraulic cooling system. The hydraulic cooling system can also be designed as a central cooling system for hydraulic and tool cooling.

In a further embodiment of the invention, at least one heat pump is designed as a water-air heat pump. As a result, the medium raised to a higher temperature level by the heat pump is air, which can be fed directly to the plastic granulate as a drying gas.

Alternatively or additionally, a heat pump can also be designed as an air-water heat pump or as an air-air heat pump. As a result, the ambient air temperature, which is regularly high in plastic injection molding operations, is used to reduce the temperature of the at least one drying gas stream.

In a further development of the invention, a preferably electrical heating element is arranged downstream of at least one heat pump. Depending on the plastic granules to be dried, this allows additional heating of the drying gas if necessary.

Alternatively or additionally, the at least one heat pump can be connected to other heat sources, such as electroplating systems, air conditioning systems, compressors, a combined heat and power plant or even a hall cooling system.

In a further embodiment of the invention, the drying gas source is formed by a compressed gas source, in particular a compressed air source, or by the drying gas outlet of an adsorption dryer. At least one sensor for detecting the temperature and/or the dew point in the drying container is preferably arranged on the drying container, with a control and regulating device for controlling at least one drying gas volume flow being arranged, which is connected to the at least one sensor. This makes it possible to minimize the drying gas required to dry the granules, which further reduces the energy requirement.

Other developments and refinements of the invention are specified in the remaining subclaims. An exemplary embodiment of the invention is shown in the drawing and is described in detail below. The only 1 shows the schematic representation of a device for drying plastic granules.

The device chosen as an exemplary embodiment for drying plastic granules according to 1 consists essentially of a drying container 1, which is connected to two dry gas sources, namely an ambient air source 5 and a compressed air source 6. The drying container 1 comprises a hollow cylindrical first section 11, which is followed by a funnel-shaped second section 12, which has a removal opening 13 at the end . A first gas guide channel 2 is arranged in the cylindrical section 11 and has a gas outlet 21 which is aligned towards the removal opening 13.

In the funnel-shaped second section 12 of the drying container 2, a second gas guide channel 3 is arranged, which has a gas outlet 31, which is also directed in the direction of the removal opening.

The first gas guide channel 2 is connected to the ambient air source 5, which is formed from a blower 51, a first heat exchanger 52 connected downstream and an electrical heater 53 connected downstream of this. The second gas guide channel 3 is connected to a drying gas source 6, which is formed from a compressed air source 61, a second heat exchanger 62 connected downstream and an electric heater 63 connected downstream of this, to which it is connected via an expansion valve 64.

The first heat exchanger 52 and the second heat exchanger 62 are connected to a water-water heat pump 4, which is connected to a cooling water tank 7, from which they heat water from the return lines of the ver connected injection molding tool 8 and the cooling system of the injection molding machine 9 connected to it.

On the inner wall of the drying container 1, a dew point and thermal sensor module 14 is arranged, which is connected to a control and regulating device 15, which is set up to record the temperature and dew point in the drying container 1 on the basis of the measured values determined by the sensors of the sensor module 14 to adjust stored default values. For this purpose, the control and regulating device 15 is connected to the blower 51 to control the volume flow of the ambient air source 5 and to the expansion valve 64 to control the volume flow of the compressed air source 6.

To dry plastic granules located in the drying container 1, relaxed compressed air is passed through the second heat exchanger via the expansion valve 64, where it is heated by the heated water supplied by the heat pump 4 and via the heater 63, where additional heat can be supplied if necessary. is introduced into the drying container 1 via the second gas guide channel 3. The heat pump 4 is fed with heated cooling water from the cooling water tank 7 and brings it to a higher temperature level via a compressor before it is fed to the second heat exchanger 62.

Heated ambient air is supplied to the plastic granules via the blower 51 via the first gas guide channel 2. The ambient air is supplied to the first heat exchanger 52, where it is heated by the heated water supplied by the heat pump 4 and is introduced into the drying container 1 via the heater 33, where additional heat can be supplied if necessary, via the first gas guide channel 2. This heated ambient air converts the water contained in the granules into the gas phase. At the same time, heat energy is supplied to the drying gas, which increases its water absorption capacity again.

The temperature and the dew point of the drying gas in the drying container, in this case drying air, is continuously recorded via sensors of the dew point and thermal sensor module 14 and reported to the control and regulating device 8, which determines the temperature and the dew point by controlling the fan based on stored default values 51 on the one hand and the expansion valve 63 on the other hand.

By arranging several gas guide channels separately fed with drying gas, a different flow rate and/or amount of drying gas can be set, whereby the flow of drying gas through the plastic granulate can be adjusted in more detail.

Although drying air is used as the drying gas throughout the above exemplary embodiments, the invention is not limited to the use of drying air. Of course, the use of all drying gases suitable for drying plastic granules is covered by the invention, in particular the use of inert gas such as nitrogen for drying plastic granules that are prone to oxidation.

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 202017107185 U1 [0003]
• EP 2399718 A1 [0005]
• EP 3702710 A1 [0006]

Claims (7)

Device for drying plastic granulate, comprising a drying container (1) which has a removal opening (13) at the end and at least one gas guide channel (2, 3) which is connected to a drying gas source, with means for heating at least one drying gas stream being arranged, characterized that the means for heating the at least one drying gas comprise at least one heat pump (4). Device according to Claim 1 , characterized in that the heat pump (4) is connected to a cooling fluid reservoir (7) which is connected to the cooling circuit of at least one injection molding tool (8). Device according to Claim 1 or 2 , characterized in that the heat pump (4) is connected to a cooling fluid reservoir (7) which is connected to the hydraulic cooling system of at least one plastic injection molding machine (9). Device according to one of the preceding claims, characterized in that at least one heat pump (4) is designed as a water-air heat pump. Device according to one of the preceding claims, characterized in that a preferably electrical heating element (53, 63) is arranged downstream of at least one heat pump (4). Device according to one of the preceding claims, characterized in that the drying gas source is formed by a compressed gas source, in particular a compressed air source (61). Device according to one of the preceding claims, characterized in that at least one sensor (14) for detecting the temperature and/or the dew point in the drying container is arranged on the drying container (1), with a control and regulating device (15) for controlling at least a drying gas volume flow is arranged, which is connected to the at least one sensor (14).

Images