The present invention regards a refiner plate segment as being defined by the preamble of claim 1. The invention also regards a refiner apparatus as defined in claim 5 and a method of refining a saturated cellulosic material according to claim 11. The present invention regards a disc-type refiner apparatus of a refiner plate steam management system.
The present invention is primary related to paper making industry, and refiner producers especially. The invention also regards refiners per se and pulp producing units. It can also be related to making of fiber boards etc. It also relates to Research and Development projects especially having an object to improve energy efficiency in Thermo Mechanical Pulp TMP plants or similar. However, the present invention is not limited to these areas, but also other grinding process management systems as well.
There have been several attempts to improve the efficiency in the grinding of cellulosic fiber material making a high quality pulp for e.g. paper industry. Paper making industry using refiners has interest in saving energy and there is a desire to balance energy consumption and the cellulosic fiber material refining process in an optimal way.
U.S. Pat. No. 6,607,153 discloses a refiner plate steam management system comprising a plurality of bars and grooves for refining a lignocellulosic material. The bars are arranged in a certain pattern for forming a path for receiving and transmitting steam generated during the refining process. Dams are positioned in the grooves at suitable positions for retarding the movement of the lignocellulosic material. The prior art system provides a pressure peak that prevails in the mid section seen in radial direction of the segments, wherein the steam flows radially outward from outer side of pressure peak and radially inward (backward) inside the pressure peak, i.e. against the material feed.
Prior art refining systems have high energy consumption and the flow-through of cellulosic material to be grinded is rather slow and not efficient. The quality of the achieved pulp is often not the same for one production cycle as for another and the refiner plate segments have to be changed quite frequently due to high wear of the grinding bars of the segments.
There is a need to improve current refining systems and refiners. The present invention is provided to save energy for refining procedures and save time in production of e.g. paper. The present invention is also provided to minimize the maintenance and service cost for refiners. The present invention is also provided for improving pulp quality and having an adequate and consistent level of quality in production.
The invention is provided for solving a problem defined by the enclosed independent claims and related to the technical field.
This has been achieved by a refiner plate segment as defined in the introduction and being characterized by the features of the characterizing part of claim 1.
In such way is achieved a refiner for use in a cost-effective manner by reducing the consumption of energy by means of a steam explosion process and still achieving an improved and uniform quality of biomass pulp for the production of e.g. paper. By means of such “explosion pulping” of the—with liquid, e.g. pure water—saturated cellulosic material (and grinded by the discs), a sudden volatilization of the liquid, entrapped within interstices (pores) of the cellulosic material, is achieved. Thus literally, an “exploding” of the material is noticed when ejected from the refining gap and beyond the outer edge to the outer environment, i.e. from high pressure environment to lower pressure environment. By means of the high pressure environment in the refining gap, which high pressure being increased by means of the barrier arrangement and maintained out to the outer edge of the disc arrangement (comprising at least two grinding discs), the pressure liquid of the saturated cellulosic material can be retained in liquid phase all the way out to the outer edge within the refining gap. Due to the achieved high pressure in the refining gap, the boiling point of the liquid (pure water or mixed water with chemicals or other) of the material can be raised compared with traditional refiners. This implies a boiling point (steam point) at relatively high temperature, thus achieving an extremely cost-effective refining process of the pulp in the refining gap. The refiner plate is combined with other refiner plates and being mounted on the discs to reach optimal grinding. The grinding bars of the respective plate segment are oriented in such way that a pumping of the saturated cellulosic material is achieved propelling the material in radial direction and/or in direction towards the outer edge. At the same time, the centrifugal force, achieved by the rotation of the at least one disc, also forces the hot saturated cellulosic material (the water being in liquid phase) towards the outer edge. By means of the barrier arrangement provided at a limited area of the disc outer edge, and the pump action of the discs, the centrifugal force, and the high boiling point of the liquid of the material due to the created high pressure, the vaporation is controlled to be performed at the outer edge perimeter of the disc arrangement. The vaporation is thus performed in a step of bringing the grinded fiber material from high pressure to low pressure outside the refining gap and barrier arrangement thereby achieving the above-mentioned “explosion pulping”. Upon the sudden discharge of the material/water (liquid)/steam mixture from the refining gap, the water (liquid) trapped within the interstices of the cellulosic material will go to steam, thereby providing the necessary energy to produce a high quality “fluffy” pulp mass suitable for e.g. paper making. Vaporation is herein defined as change of a liquid or solid substance to a gas or vapor.
The cellulosic material being fed from centre inlet opening of the refiner disc to the refining gap by means of a pump (e.g. a screw pump with a single screw that rotates in a cylindrical cavity, thereby moving the material along the screw's spindle towards the refining gap) arrangement in communication with the inlet opening. The cellulosic material being fed serves as a “plug” and has a sealing functionality even more providing the pressure in the refining gap to increase.
It is suitably to provide an adjustable gap sensor (AGS) for detecting the width of the refining gap. It can preferably be mounted in the disc segment adjacent the outer edge of the disc, Of course, also other positions are possible for measure the refining gap. It is suitably to use an AGS of the type described in WO 2005/083408.
It is preferably to control that the steam point is near (located before i.e. upstream the barrier arrangement) the outer edge in the refining gap. That is, during use of the refiner it is suitably to control the refiner performance from detected fiber concentration. This can be made by correlating water amount inflow in the refining gap. One way to detect the position of the steam point is to use a system disclosed in the Swedish patent application SE 1351299-1. Such continuous measurement of the steam point will contribute to an improved production using the refiner apparatus disclosed herein.
Suitably, the barrier arrangement comprises a continuous lateral bar member.
In such way is achieved an optimal sealing of the refining gap. As the disc per se carrying the segments is somewhat resilient, in case of overpressure, the disc will release the pressure automatically. Thereby is provided overload security functionality.
Preferably, the height of the barrier arrangement, such as a circular bar provided at the grinding surface of the disc when the segments are provided, is the same as the height of the grinding bars.
Alternatively, the barrier arrangement extends along the outermost edge of the segment and faces the opposite disc.
In such way only one of the discs has to be provided with a barrier arrangement still achieving the higher pressure and a well defined evaporation point at the outer edge of the discs.
Preferably, the barrier arrangement comprises a lateral barrier bar having an inner side facing the inlet opening of the refiner.
Suitably, the barrier bar also comprises an upper side extending at the same plane as the grinding bars upper sides. This will promote cost-effective edging and sharpening of the segment, as an edging apparatus with easy handling can be moved over the grinding bars and barrier bar during sharpening.
Preferably, the barrier arrangement comprises a plurality of barrier bars arranged in the outer edge of the segment.
Suitably, the barrier bar exhibits an outer side opposite the inner side of the barrier bar, which outer side preferably is even with the outer side perimeter of the disc and segment edge sides.
Preferably, the barrier arrangement faces ends of channels formed by grinding bars of the segment.
In such way is the built up pressure achieved by means of the pumping effect by the grind bars and the centrifugal forces and moved out in a well defined position to the outer edge of the disc (i.e. of the segment) and the barrier arrangement. The material is grinded by the opposite grinding bars of respective disc moving in relative motion to each other and the material being grinded are propelled in a direction towards the outer edge of the disc (i.e. of the respective segment) in said channels of the segments.
This has been achieved also by a refiner apparatus characterized by the features of the characterizing part of claim 5.
Thereby the effect of grinding the material can be decreased and energy needed for the process is lower than current refiners, still making a high quality pulp for e.g. paper. This is achieved by the use of the barrier arrangement in the outer edge of the discs and by making use of a so called “masonite effect”, i.e. a sudden volatilization of the liquid entrapped within interstices (pores) of the cellulosic material.
In such way is achieved a cost-effective refiner apparatus. By means of the high pressure environment in the refining gap, the boiling point of the water (pure water or mixed water with chemicals or other) of the material can be raised compared with traditional refiners. This implies a boiling point at relatively high temperature, thus achieving an extremely cost-effective refining process of the pulp in the refining gap. The grinding bars of the respective plate segment are oriented in such way that a pumping of the saturated cellulosic material is achieved propelling the material in radial direction and/or in direction towards the outer edge.
At the same time, the centrifugal force, achieved by the rotation of the at least one disc, also forces the hot saturated cellulosic material comprising hot water in liquid phase towards the outer edge. By means of the barrier arrangement provided at a limited area of the disc outer edge, and the pump action of the discs, the centrifugal force, and the high boiling point of the liquid of the material at the outer edge, the vaporation is controlled to be performed at a well-defined area of the outer edge of the refiner. Thereby no forces act upon the material backwards in a direction towards the inlet opening. Upon the sudden discharge of the material/water/steam mixture from the refining gap, the water trapped within the interstices of the cellulosic material to steam thereby providing the necessary energy to produce a high quality pulp mass suitable for e.g. paper making. The cellulosic material being fed trough the inlet opening serves as a “plug” and has a sealing functionality even more providing the pressure in the refining gap to increase. The present refiner also propels the material by means of the pump action provided by the grinding bars to an higher rate than current refiners. The pump action of the present discs presents a so called “feeding” of material from the inlet opening towards the outer edge.
In such way is also achieved that all quality parameters of the grinded material is improved. That is, the rate for drying the pulp from water is high, thus further improving the efficiency of the refiner. By moving the steam point of the water to the outer edge of the discs, at which position the pressure falls to lower pressure, there is guaranteed that no unnecessary motion forward and backward (in radial direction) of the steam point is actual in the present refining gap. Such movement otherwise according to prior art must be counter-acted by adding or removing water to the material. For example, if the material has a lack of water, there is needed a very high effect to grind the material. By the present well-defined steam point positioned at the outer edge, a more similar quality and more even production with less fluctuations in production is achieved. As there is no need any longer to taper the discs towards each other, the present disc segments will have longer life as no wear will be present caused by taper adjustments of the discs.
By the present improvements, the energy consumption is extremely reduced compared with current refiners, as paper making of today requires a lot of energy. The present refiner thus promotes for “green technology” applications.
Preferably, the barrier arrangement extends continuously along the outer edge.
In such way is achieved a proper sealing of the refining gap, still the barrier arrangement (bar) forms a narrow aperture (slot) and the opposite positions (with or without any barrier arrangement).
Suitably, the disc arrangement comprises a set of refiner plate segments provided with said barrier arrangement.
In such way a choke of the flow-through of material is provided up to the circumferential edge of the refiner disc arrangement. Such choke means that a high pressure prevails all the way out to the outer edge for keeping the boiling point at said outer edge before the material is “exploded” from the refining gap and outer edge to the outer environment, i.e. from high pressure environment to lower pressure environment. At such sudden volatilization of the liquid entrapped within interstices (pores) of the cellulosic material, the above-mentioned “explosion pulping” is achieved. The discharge of the material/water/steam mixture to the lower pressure involves that the water trapped within the interstices of the cellulosic material will steam, thereby providing the necessary energy to produce a “fluffy” pulp mass suitable for e.g. paper making.
Preferably, the disc arrangement comprises grinding bars being oriented relative each other and relative the refiner inlet opening in such way that an added pump action propels the material towards the outer edge during rotation of at least one disc.
The grinding bars of the respective plate segment are oriented in such way that a pumping of the saturated cellulosic material is achieved propelling the material in radial direction and/or in direction towards the outer edge. The disc arrangement thus may comprise discs, each of which having grinding bars, which discs when rotating relative each other (just one rotating or both) act as a radial-flow pump or centrifugal pump.
Suitably, the barrier arrangement is formed by grinding bar ends ending at the peripheral area of the outer edge.
In such way is achieved that the grinding edges of the grinding bars in an optimal way are used all the “way out”.
Preferably, the opposed discs comprise mutual complementary barrier bars to increase said pressure.
By using the same configuration of both discs, the refiner plate segments can be made with identical pattern and barrier arrangements for mounting at both discs. This is cost-effective, both for producing the segments and for maintenance and service at the site as the segments can be the identical for efficient handling.
This has been achieved also by the method characterized by the features of the steps of claim 11.
In such way is achieved high rate (high speed flow-through of material compared with current refiners) for material to pass the refining gap due to the pump action. In such way is achieved a high pumping effect. For saving energy is also the grinding effect less requiring energy as the “masonite” effect will take care of making a high quality pulp. Old current prior art refiners still use the grinding procedure to a greater extent to refine the material, which involves high consumption of energy. In such way is achieved that a high pump effect is provided for reaching the movement of the boiling point of the material out to the outer edge to choke the flow of hot material at a well-defined position of the outer edge for making high pressure and increasing the temperature for vaporisation at the well-defined position.
Preferably, the grinding bars being oriented relative each other and relative the refiner inlet opening in such way that the radial pump action propels the material towards the outer edge. Suitably, the method is added with the step of adjusting the width of the refining gap on-line by means of a control unit associated with an AGS system, for example of the type disclosed in WO 2005/083408.
Alternatively, the control unit is also associated with a temperature/conductance indicating sensor as e.g. disclosed in SE 1351299-1 for controlling the water supply to the material, wherein the boiling point (steam point) can be controlled to be positioned in the well-defined area achieved by the barrier arrangement.
Preferably, the sealing of the inlet opening is made by the feeding step of moving the material through the inlet opening, wherein the material in the inlet opening also acts as a plug.
In such way the high pressure in the refining gap can be maintained and the motion of the material and liquid is guaranteed towards the outer edge and the pressure peak point is forced out to the outer edge and the barrier arrangement.
Suitably, the step of exposing the material is controlled by a control unit coupled to a gap sensor and/or material mixture detector and/or disc rotation measuring device and/or gap pressure detector means.
Preferably, the outside of the outer edge is performed in a housing encompassing the disc arrangement.
In such way the high quality fine pulp material can be collected outside the disc arrangement and transported to a collecting station for further transportation to e.g. a paper making plant.
The present invention will now be described by way of examples with references to the accompanying schematic drawings, of which:
Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, wherein for the sake of clarity and understanding of the invention some details of no importance are deleted from the drawings.
The following
The grinding bars 3 being oriented relative each other and relative the refiner inlet opening 21 in such way that the radial pump action propels the material M towards the outer edge 7 as shown in
In
In
In such way is achieved that on-line measurement is achieved within a zone between the refiner discs.
It will thus be possible to control the refiner performance from detected fiber concentration and/or steam point. An user of the refiner can thus cost-effective perform automatic recalibrations during production and continuously correlate water amount inflow in-between the refiner discs, thereby controlling the position of the steam point in radial direction of the refiner discs. Such continuous measurement implied improved production rate as well.
The position of the steam point is important for cost-effective reaching the production of proper pulp quality and at the same time not unnecessary overloading of the refiner, which in turn involves high power consumption.
Step of exposing the material is controlled by a control unit coupled to a gap sensor and/or material mixture detector and/or disc rotation measuring device and/or gap pressure detector means.
The present invention is of course not in any way restricted to the preferred embodiments described above, but many possibilities to modifications, or combinations of the described embodiments, thereof should be apparent to a person with ordinary skill in the art without departing from the basic idea of the invention as defined in the appended claims. The fiber pad material preferably comprises cellulose fibers for making paper pulp.
Number | Date | Country | Kind |
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1450143-1 | Feb 2014 | SE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/SE2015/050134 | 2/6/2015 | WO | 00 |