DE102015109823A1 - Process and tempering and pressing device for the production of inorganic bonded wood-based panels - Google Patents

Abstract

The invention relates to a tempering and pressing device for inorganically bound wood-based panels, comprising at least one cassette for receiving a binder wood chip mixture as a chipboard and means for pressing the cassette, which characterized in that the tempering and pressing device means for active, uniform and controllable heating and / or active cooling of the chip web. The invention further relates to a process for the production of inorganic bonded wood-based panels in a tempering and pressing device.

Description

The invention relates to a method and a tempering and pressing device for the production of inorganically bonded wood-based panels.

The main field of application of the invention is in the production of cement-bonded chipboards, which are also referred to as CBPB (English: cement bonded particle board) and in other inorganic bonded wood materials.

Cement-bonded chipboards are used, for example, as planking in the interior and exterior of buildings. Depending on the design, such plates have good sound and heat protection characteristics, high chemical and biological resistances and moisture resistance. Cement-bonded chipboards are used, for example, as floor installation panels, as interior wall and ceiling coverings and as facade cladding or plaster base panels in a variety of configurations, even in the exterior area.

From the above-mentioned universal applications of this wood-based panels there is a great need for this building material, in particular an efficient production method with short production times and the generation of desired properties of the plates with the required quality are important criteria in the production of such plates.

Cement-bonded chipboards have long been known in the art. For example, goes from the US 3,271,492 a method of making a non-porous slab of wood chips and Portland cement. The compositions of the plates are different depending on the desired results in terms of the field of application of the plates to be produced. For example, a common recipe for cementitious chipboard is such that nonwovens are produced from 20 to 25 percent by weight of wood chips, corresponding to 55 to 60 percent by volume, and 70 to 75 percent by weight Portland cement, as well as additives and water, by cold or hot pressing Plates are pressed.

During production in the cold-pressing process, a cement-wood chip mixture is produced and scattered to a chipboard. Up to 50 scattered nonwovens are pressed in the stack under high pressure at 1.5 to 3 MPa and clamped in a cassette. The stretched cassette then runs in 6 to 8 hours through a tempered channel at a temperature of 60 to 70 ° C. This is the early strength-hardening curing of the plates. This is followed by a maturity of several days followed by drying with post-treatment steps of the board.

In contrast to the cold-pressing process, the hot-pressing process is characterized in that a cement-wood chip formulation specially adapted to the hot-pressing process and a pressing temperature of 90 ° C. lead to an early strength of 15 to 25 minutes, so that the scattered nonwovens in a heated one-storey Press can be pressed. The post-treatment steps correspond to those of the cold pressing process.

With regard to the composition of inorganically bound wood-based panels are for example from DE 7519611 known with Sorelzement bonded particleboard. The composition is characterized by the addition of magnesium oxide and an aqueous magnesium chloride solution, as well as water glass and calcium chloride. In addition to various compositions of the inorganically bound wood-based panels, the design within the wood-based panel with the formation of various layers within a panel is also known in the prior art. For example, goes from the DE 10 2011 014 396 B4 a cementitious, containing as a wood chip material filling material construction plate, which has a middle layer, a lower cover layer and an upper cover layer, wherein between the middle layer and the respective cover layer is provided in each case an intermediate layer. The intermediate layers contain coarse wood chips compared to the other layers.

The wood-based panels and the methods used to produce them adhere to various disadvantages. On the one hand, the production processes are characterized by a very high expenditure of time and energy and, on the other hand, with regard to their parameters, the plates produced are in some cases not optimally designed in relation to the effort involved.

The object of the invention is therefore to provide a method and a tempering and pressing device for the production of inorganically bound wood-based panels available, the process should be designed time and energy efficient and simplify the tempering and pressing device, the production of the inorganic bonded wood-based panels and unify.

The object is achieved by a method and a tempering and pressing device with the features of the independent claims. Further developments are specified in the dependent claims.

The object of the invention is achieved in particular by the fact that for the production of the inorganically bound wood-based panels a Tempering and pressing device is used, which has at least one cassette for receiving a binder wood chip mixture as Spanvlies and which in addition to the means for pressing the nonwoven to the plate in the cassette also means for active heating and / or active cooling of the chip web. The active heating of the fleece serves to preheat the fleece before bracing and pressing. The active heating or cooling of the nonwoven serves to heat or cool during the curing of the nonwovens in the strained cassette. Thus, the means for active heating in the steps of preheating and heating to cure are effective. In contrast to the passive heating and cooling known in the prior art, active heating or cooling is to be understood as meaning that the heat transfer not only takes place from the outside to the inside via heat conduction within the press plates, but that the heat is dissipated in the entire plane of the plate or plate Fleece is registered in this. This is done, as explained in the following, by the configuration of the contact surfaces to the surface of the nonwoven fabric as active heat exchangers or by the use of heat transfer methods without contact with the surface of the nonwoven. Common to the methods for actively heating or cooling the nonwovens is that the nonwovens are heated uniformly over the contact surfaces or in the entire volume. Through the active heating and cooling, it is possible to control the temperature profile during heating or cooling of the nonwovens or plates or regulate. This, it was recognized, is the prerequisite for the application of specifiable and optimal temperature profiles during preheating and the heating of the webs in the various stages of the production of the plates. The passive heating according to the prior art is done by heating the air in a curing oven, wherein the heated air heats the heat-conductive press plates at the edges and the heat is then conducted via heat conduction in the press plates into the interior of the nonwoven or plate stack.

It is of particular importance that the tempering and pressing device is expanded in the usual design as a cassette with press plates to means for the function of the active temperature control of the cassette itself and the individual press plates. A preferred embodiment of the device is that within the cassette a plurality of chip-webs are arranged, which are separated by press plates. In this case, the cassette and / or the pressing plates are equipped with means for active heating and / or active cooling of the chipboard and it is thus possible to preheat the nonwovens independently of the subsequent heating to cure the nonwovens to defined plates. It has been found that a defined and reproducible preheating prior to compression and tensioning of the webs and prior to heating to cure results in significant improvements in the properties of the boards.

Preferably, the means for the active heating of the chip mat are carried out as electrical resistance heating, wherein in turn preferably the resistance heating is laminated onto the press plates and / or the cassette or of course the heat-transmitting surfaces of these elements.

Alternatively, the means for active preheating of the chipboard are designed as infrared radiators and are used, for example, after web formation and before compression and bracing in the course of preheating the nonwovens.

Again alternatively, the means for active preheating or heating to cure the chipboard are formed as high-frequency or microwave heating, wherein the heating takes place after the web formation either preheating or combined for preheating and heating for curing.

For preheating the nonwovens, the infrared radiators or the high frequency or microwave heating are arranged in a pressing device upstream tempering, whereas the heating for curing by high frequency or microwave heating can be done in a compact integrated tempering and pressing device using press plates made of plastic. Thus, the nonwovens can be preheated in this constellation in the cassette or in the stack and heated to cure. High-frequency or microwave heating is understood to mean the heating of substances by the action of electromagnetic fields, using frequencies of 10 kHz to 300 GHz.

A particularly preferred embodiment consists in that the means for active heating and / or active cooling of the chip web are formed as channels through which heat or coolant fluid can flow in the press plates and / or in the walls of the cassette. Thus, the press plates and / or the cassettes themselves are designed as heat exchangers, for example as plate heat exchangers, and the chip webs are actively heated via the plate surface directly for preheating and for heating.

It goes without saying that, although with some increased use of equipment, but with excellent results, combinations of said means for active heating and / or Cooling of the chipboard can be done. This makes it possible, in particular, for synergistic effects of the individual types of heat input to be achieved with regard to the dynamics of the heat transfer processes. A combination of the methods consists in the preheating of the webs by means of infrared radiator or microwave, while the press plates are made of good heat conducting plastic with flow-through channels and the active heating is realized in the compressed and strained state by a controllable heat transfer fluid.

• – Mischen der Komponenten, wie Holzspäne, Zement, Abbinderegler, Zusatzstoffe und Zusatzwasser,
• – Streuen der Vliese in mehreren Schichten,
• – Verpressen und Verspannen mit Aufstapeln der Vliese und Stapelverpressung von mehreren Vliesen in einer Kassette und Verspannen der Kassette,
• – Aushärten der Vliese in der verspannten Kassette zu Platten,
• – Reife der Platten,
• – Trocknung der Platten und
• – Nachbehandlung der Platten, dadurch gekennzeichnet, dass
• – vor dem Verpressen und Verspannen eine Vorwärmung der Vliese in der Kassette mit Mitteln zur aktiven Beheizung der Vliese erfolgt, wobei
• – die Vorwärmung der Vliese in der Kassette in Abhängigkeit der Holzart und Rezeptur auf Temperaturen zwischen 30°C und 40°C erfolgt und dass
• – das Aushärten der Vliese in der verspannten Kassette zu Platten nach einem vorgebbaren Temperaturverlauf geregelt wird.

The object of the invention is also achieved by a process for the production of inorganically bonded wood-based panels in a tempering and pressing apparatus which has the following method steps:

• - mixing components such as wood chips, cement, setting regulators, additives and make-up water,
• Spreading the nonwovens in several layers,
• Pressing and clamping with stacking of the nonwovens and stack pressing of several webs in a cassette and clamping the cassette,
• Hardening of the nonwovens in the tensioned cassette to plates,
• - maturity of the plates,
• - Drying of the plates and
• - After treatment of the plates, characterized in that
• - Before pressing and clamping a preheating of the nonwovens in the cassette with means for actively heating the nonwovens takes place, wherein
• - The preheating of the nonwovens in the cassette depending on the type of wood and recipe is carried out at temperatures between 30 ° C and 40 ° C and that
• - The curing of the nonwovens in the strained cassette is controlled to plates according to a predetermined temperature profile.

The term nonwoven means non-wovens for the production of wood-based panels. As an alternative to the conventional curing of the plates in a separate oven or hardening channel, hardening of the nonwovens in the clamped cassette also takes place directly to plates with the means for heating the nonwovens in the cassette. As a result, a direct, low-loss energy input is generated directly into the chipboard and it can account for the equipment-consuming and high energy consumption marked curing oven.

According to one embodiment of the invention, the curing of the nonwovens in the clamped cassette to plates at least partially feasible in a Aushärtekanal, so in turn synergetic effects can also be used with respect to the use of different energy sources for heating.

It has been found to be particularly advantageous that the time for preheating the nonwovens is at least between 5 and 15 minutes and the time for curing the nonwovens is between 180 and 420 minutes.

The concept of the invention is based on the finding that a targeted and reproducible preheating of the nonwovens in or outside of the cassettes leads to a surprising improvement in the achievable parameters with regard to transverse tensile strength and flexural strength and, moreover, a significant reduction of the curing time is possible. The preheating of the cassettes and thus the compressed nonwovens is dependent on the procedure in the prior art of the stored in the chuck heat energy, the thermal conductivities and heat capacities of the materials used as well as the ambient temperature and the heat transfer properties. The nonwovens, and in particular the geometric nonwoven center, are poorly heat-achieved by the known methods and procedures, and the temperatures achieved in the nonwoven core are distributed differently across the stack height and by the combination of the above-mentioned influences of a random nature.

Thus, it was surprisingly found that a heating of the nonwovens during curing is dependent on various influences. For example, the Vorerwämung the nonwovens, the ambient temperature and thus the temperature of the components and components of the web, the thermal conductivity of the materials themselves and the system components and the heat transfer between the system components and the materials. The conventionally existing and accepted differences in the temperature gradients in a chuck cassette lead to significant differences in the resulting disk properties. Depending on the type of wood and binder composition used, a particular temperature curve during curing may advantageously and conceptually affect the resulting sheet properties. By setting an optimal course of the temperature distribution in the nonwovens significant improvements are achieved. As a result, the homogenization of the temperature curves for all plates in a stack and the optimization of the temperature profile leads to an improvement and a lower variance of the plate properties. The targeted and controlled heating of all nonwovens in a stack from the time just before the compression process can be implemented in various ways. Particularly suitable is the electrical heating of the nonwovens by on the coming into contact with the nonwovens surfaces of the press plates and cassette laminated heating elements, wherein the heating elements be laminated directly on the press plates and the cassette. Another advantageous possibility of heating and temperature control by optionally cooling is achieved in that the press plates are configured with channels in the manner of a heat exchanger, wherein the heating or cooling media then flow through the channels of the heat exchanger and heat the press plates and the cassette walls or cool. Hot or cold water, thermal oil or brine are used as heat or cooling medium.

Another possibility is to heat the individual webs or the entire package for preheating by means of infrared radiation or high-frequency or microwaves. Of particular importance in the temperature curves is the regulation and control of the same, so that a precisely predetermined temperature profile can be achieved in coordination with recipe and wood species.

The procedure according to the invention achieves various advantageous effects. Controlled heating of the nonwovens during the preheating and during the heating during curing leads in particular to good plate properties, if a suitable depending on the type of wood and recipe preheating of the web is applied shortly before the compression and tensioning process. An optimized temperature profile leads to significantly better plate properties. Property improvements of the individual parameters by up to 30% are possible. In addition, the use of temperature control makes it possible to use wood species that were previously not available as a possible raw material for the production of cement-bonded chipboard. In particular, beech wood or better beech chips are thus used for the production of cement-bonded chipboard. Beechwood can not be used according to the usual procedures of the prior art, as beech wood ingredients inhibit hydration. By preheating the nonwoven can now be used for the production of cement-bonded chipboard at a suitable temperature curve during curing now also beech wood.

Further details, features and advantages of embodiments of the invention will become apparent from the following description of exemplary embodiments with reference to the accompanying drawings. Show it:

1 : Temperature-time diagram for the production of wood-based panels,

2 : Temperature-time diagram for the production of wood-based panels with spruce chips and

3 : Temperature-time diagram for the production of wood-based panels with beech shavings.

In 1 is a temperature-time diagram in logarithmic representation of the time in minutes on the abscissa. The temperature inside a Spanvlieses is at the beginning of the production at ambient temperature level of about 20 degrees Celsius. The temperature profile is shown as a dash-dot line over time. The process of preheating lasts until the beginning of the compression and tensioning of the web in the cassette and is, as indicated by the vertical line, at a time of about 15 minutes. Within this phase of preheating, the fleece has reached a continuous temperature of 25 degrees Celsius. After the tensioning and compression of the cassette has taken place, the nonwoven is heated to 60 degrees Celsius within about 400 minutes. The phase of preheating and the phase of heating for curing are clearly visible through the unsteady course and the formed inflection point of the curve.

In 2 is a temperature-time diagram for the production of wood-based panels using spruce chips shown. The solid line indicates the temperature profile in the production of wood-based panels according to the prior art. The dash-dot line shows a warming as preheating within 15 minutes to a temperature of 35 degrees Celsius with subsequent heating to cure to a temperature level of 55 degrees Celsius after about 100 minutes. The heating of the fleece and the plate according to the invention leads to a significantly steeper increase in the core temperature of the fleece during the preheating and the curing by the use of heat transfer agents directly on the press plates.

In 3 Finally, a temperature-time diagram for the production of wood-based panels is represented with beech chips. Again, a temperature history of the prior art is shown as a solid line. The optimized temperature profile is shown as a dashed line. The preheating to a temperature of 35 degrees Celsius takes place already after 10 minutes and the further heating of the beech shavings takes place up to a temperature of 62 degrees Celsius, which is reached after 200 minutes.

Overall, the representations of the 2 and 3 in that the temperature in the core of the chip web increases significantly faster than after the state of the art. This is due to the use of means for actively heating the chip webs, wherein the means for active heating are preferably arranged in the press plates and the cassette. In order to be able to better control the temperature profile, in particular at the end of the heating and in the case of exothermic reactions during the curing process, the means for heating are preferably also designed to actively cool the chip web. Such a configuration is given in an inefficient manner when, for heat transfer, the means for active heating and / or active cooling of the chip mat are flow-through channels of heat or refrigerant fluid, which channels are formed in or on the press plates and / or the cassettes. A cycle of heat or refrigerant fluid can be installed with little effort and can replace a complex curing possibly even completely. This leads to a reduction in investment costs, since a curing oven accounts for a significant proportion of the investment costs in the production of wood-based panels.

As a result of the changed temperature profile during the production of the wood-based panels, improvements in the mechanical properties result from the use of the optimized temperature curves in comparison with the production method according to the prior art. With spruce shavings as a wood component of the nonwovens, the flexural strength increases by 30% and the transverse tensile strength increases by 20%. With beech shavings as a wood component of the nonwovens, the flexural strength increases by 20% and the transverse tensile strength increases by 20%.

A general procedure for the production of cement-bonded chipboard consists of the following process steps:
First, the components are mixed according to the recipe. In particular, chips, cement, setting regulators, additives and make-up water are brought into contact with one another in the desired ratios and mixed. This is followed by scattering of the nonwovens, wherein, for example, three layers, an upper covering layer, a middle layer and a lower covering layer, are produced. This is done, for example, with three scattering heads or with two scattering heads and a throwing sight.

Subsequently, the fleeces are pressed and braced. First of all, the nonwovens for staple compression of up to 50 nonwovens are stacked in a cassette. It is now the clamping of the cassette to produce the necessary pressing pressure for the phase of the subsequent curing. The cassette loaded in this way now passes through the hardening channel in the curing phase, which has temperatures between 60 and 80.degree. The residence time in the curing channel is usually between 6 and 8 hours. After curing, the plates are unwrapped in the process step of maturation and stored for 12 to 14 days. This is followed by the process step of drying, wherein the drying of the plates takes place in the drying oven at temperatures between 90 and 110 ° C over a period of between 5 to 8 hours. Finally, there is a post-treatment, which consists of conditioning, grinding, cutting and shipping.

The inorganically bonded wood-based panels according to the invention are now preheated prior to pressing and bracing. This is advantageously done by heating the already layered in the cassette webs before bracing. The heat is thus entered directly into the nonwovens via the cassette or via the press plates which separate the individual nonwovens. The press plates and the cassette itself are designed as a heat exchanger for the direct introduction of heat and / or cold.

According to one embodiment, the press plates and the surfaces in contact with the web are provided with electrical heating elements which are laminated onto the surfaces of the press plates and the cassette.

Alternatively, or optionally in combination with this type of embodiment of the means for heat transfer to the nonwoven fabric, the press plates can be constructed in multiple layers, with channels or pipes are provided for heating or cooling media, so that over such configured press plates preheating before the compression process and a subsequent controlled heating is possible.

Overall, it is particularly advantageous to mention that with appropriate dimensioning of the means for heat transfer and in particular the heating, the curing can be carried out completely without a curing channel. Since the heat is transferred directly to the nonwovens directly from the surfaces of the cassette and the press plates on the nonwovens, heat losses are avoidable. It is also particularly advantageous that a high dynamics of heat transfer is possible, because in contrast to a heating in curing the surrounding surfaces of the nonwoven are heated directly, whereas in a curing usually hot air as heat transfer the compact cassettes on the thermally conductive press plates from the outside must be heated internally via the heat conduction of the press plates.

A thorough heating of the nonwovens without the Aushärtekanal moreover leads to advantages, because the drying of the edge regions of the plates is reduced and beyond the Possibility of regulated cooling to the end of the process exists. This leads to lower stresses and a reduction in dehydration, especially in the exothermic phase of curing in the manufacture of the plates. As a result, higher efficiency in the heat transfer processes can be achieved. When eliminating or reducing the use of Aushärtekanals the equipment and costly high expenses for the required large volumes of air volume in Aushärtekanal can be drastically reduced and that, although by the direct heat input into the fleece and the plates better material properties of the plates can be achieved. The improved material properties result in the result that raw material savings in the plates are possible because the modified and optimized procedure better or even after reduction of raw material use consistent parameters can be achieved.

An embodiment of the invention is that the thermal conductivity of the press plate is optimized by, for example, a core of aluminum or copper is provided and a heat transfer by means of contact elements for preheating to take place before the compression process.

It is particularly advantageous to note that the controlled temperature profile during curing of cement-bonded chipboard leads to an improvement of the plate properties of about 30% and thus a possible reduction of the density while maintaining the normative requirement and concomitant material savings is possible.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been 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

• US 3271492 [0005]
• DE 7519611 [0008]
• DE 102011014396 B4 [0008]

Claims (10)

Tempering and pressing device for inorganically bonded wood-based panels, comprising at least one cassette for receiving a binder wood chip mixture as Spanvlies and means for pressing the cassette, characterized in that the tempering and pressing means for active, uniform and controllable heating and / or active cooling the Spanvlieses has. Apparatus according to claim 1, characterized in that within the cassette a plurality of chipboard webs are arranged, which are separated by press plates and that the cassette and / or the press plates comprise means for active heating and / or active cooling of the chip web. Apparatus according to claim 1 or 2, characterized in that the means for actively heating the chip web are designed as electrical resistance heating and that the resistance heating is laminated on the press plates and / or the cassette. Apparatus according to claim 1 or 2, characterized in that the means for the active heating of the chip web are formed as infrared radiators. Apparatus according to claim 1 or 2, characterized in that the means for the active heating of the chip web are formed as high-frequency or microwave heating. Apparatus according to claim 1 or 2, characterized in that the means for active heating and / or active cooling of the chip web are formed as flowthrough of heat or refrigerant fluid channels in or on the press plates and / or the cassettes. Process for the production of inorganically bonded wood-based panels in a tempering and pressing apparatus according to one of the preceding claims with the method steps: mixing of the components, such as wood chips, cement, setting regulator, additives and make-up water, spreading of the nonwovens, pressing and bracing with stacking of the Nonwovens and stack pressing of several webs in a cassette and clamping the cassette, - hardening of the webs in the clamped cassette into plates, - maturity of the plates, - drying of the plates and - aftertreatment of the plates, characterized in that - before pressing and clamping a preheating of the nonwovens in the cassette with means for active heating of the nonwovens takes place, wherein - the preheating of the nonwovens in the cassette, depending on the type of wood and recipe is carried out at temperatures between 30 ° C and 40 ° C and that - the curing of the nonwovens in the strained cassette to e is regulated inem specifiable temperature profile. A method according to claim 7, characterized in that the curing of the nonwovens in the tensioned cassette to plates with the means for heating the nonwovens in the cassette takes place. A method according to claim 7 or 8, characterized in that the curing of the nonwovens in the tensioned cassette to plates takes place partially in a curing channel. Method according to one of claims 7 to 9, characterized in that the time for preheating the nonwovens is at least between 5 and 15 minutes and the time for curing between 180 and 420 minutes.

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