BE1022912B1 - A method for controlling the liquid level in the premixing unit of a hatschekmachine - Google Patents

Abstract

A method for controlling the liquid level in the premixing unit of a Hatschek machine comprising a plate making machine, a cement paste preparation mixer, a settling vessel, a selectifier and a premixing unit is described, wherein a level meter measures the liquid level in the premixing unit and thereby generates a measurement signal and wherein this measurement signal directs or indirectly controls a control valve that controls the amount of the portion of the cement slurry loaded water from the plate making machine supplied to the selectifier

Description

A METHOD FOR CONTROLLING THE LIQUID LEVEL IN THE PREMIXING UNIT OF A HATCHER

Technical area

The present invention relates to Hatschek machines and methods for controlling such machines, in particular the liquid level in the premixing unit of a Hatschek machine.

State of the art

Hatschek machines are widely known and are used for the production of fiber cement sheets. A few aspects of such Hatschek machines are described in US1872480 and JP5181820. In such machines, the flows of various liquids are numerous and their controls complex. The regulation of one flow often has a strong influence on the operation of other parts of the machine or on the other liquid flows themselves.

Summary of the invention

It is an object of the invention to provide an alternative control of a Hatschek machine, in particular one that guarantees a more stable operation of the settling vessel.

According to a first aspect of the invention, a method for controlling the liquid level in the premixing unit of a Hatschek machine comprising a plate making machine, a cement papermaking mixer, a settling vessel, a selectifier and a premixing unit is provided. The method comprises the step in which a first part of the cement-loaded water from the plate making machine is supplied to the settling vessel, and wherein a level meter measures the liquid level in the premixing unit and thereby generates a measurement signal and wherein this measurement signal directly or indirectly controls a control valve thereby controlling the amount of the second portion of cement-loaded water from the plate making machine fed to the selectifier.

According to some embodiments, the method may include the following steps: o Sinked cement sludge from the settling vessel is supplied to the selectifier; o Cement paste from a cement paste preparation mixer is supplied to the selectifier; o The cement mixture from the selectifier purified from hard particles is supplied to the premixing unit; o Flocculant is supplied to the premixing unit in order to obtain a mixture which is supplied to the plate making machine.

According to some embodiments, the generated measurement signal can be processed by a processing unit, which generates a control signal that controls the control valve.

In some embodiments, the level meter may be a load cell.

In some embodiments, the amount of settled cement sludge from the settling vessel supplied to the selectifier may be constant.

A selectifier is a centrifugal cleaning device used to remove hardened particles from a slurry.

According to some embodiments, the generated measurement signal can be processed by a processing unit, which generates a control signal that controls the control valve.

This processing unit can be a central processing unit, for example the CPU of a control mechanism or of a computer.

In some embodiments, the level meter may be a load cell.

A weighing cell is also known as a pressure box or load cell.

In some embodiments, the amount of settled cement sludge from the settling vessel supplied to the selectifier may be constant.

According to a second aspect of the invention, a Hatschek machine for manufacturing fiber cement plates is provided, which machine comprises • A plate making machine, • a cement papermaking mixer, • a settling vessel, • a selectifier • a premixing unit, • a first transport pipe for supplying a first part of the cement-laden water from the plate making machine to the settling vessel; A second transport pipe for supplying settled cement sludge from the settling vessel to the selectifier; A third transport pipe for supplying a second part of the cement-laden water from the plate making machine to the selectifier; A fourth transport pipe for supplying cement paste from the cement paste preparation mixer to the selectifier; A fifth transport pipe for supplying the hard particles of purified cement mixture from the selectifier to the premixing unit; • a provision for adding flocculant to the premixing unit; • a sixth transport pipe for supplying a mixture from the premixing unit to the plate making machine; • a first level meter for measuring the liquid level in the premixing unit and generating a first measurement signal; A first control valve for controlling the second part of the cement-loaded water from the plate making machine to the selectifier; • a processing unit for converting the first measurement signal to a first control signal for controlling the first control valve.

A control valve is a valve whose opening can be adjusted by means of a control signal. The control valves can be any valves, but are, for example, butterfly valves.

A transport pipe is to be understood to mean any channel, pipe or pipe, whether or not fixed or flexible, that is suitable for transporting liquid from one place to another.

According to some embodiments, the machine may further comprise at least a second control valve for controlling the amount of the premixing unit mixture that is supplied to the plate making machine via the sixth transport pipe. According to some embodiments, the plate making machine may comprise at least a first vessel in which at least one cylindrical screen is rotatably suspended in order to produce a fiber cement web, the sixth transport pipe supplying the mixture of the premixing unit to this first vessel of the plate making machine. According to some embodiments, the first vessel may comprise a second level meter for measuring the liquid level in this first vessel and for generating a second measurement signal, and wherein the processing unit converts the second measurement signal into a second control signal for controlling the second control valve .

According to some embodiments, the plate-making machine may comprise at least a second vessel in which at least one cylindrical screen is suspended in rotation for the manufacture of a fiber-cement fleece, a seventh transport pipe supplying the mixture of the premixing unit to this second vessel of the plate-making machine. According to some embodiments, the machine may further comprise at least a third control valve for controlling the amount of the premixing unit mixture that is supplied to the plate making machine via the seventh transport pipe. According to some embodiments, the second vessel may comprise a third level meter for measuring the liquid level in this second vessel and for generating a third measurement signal, and wherein the processing unit converts the third measurement signal into a third control signal for controlling the third control valve .

The independent and dependent claims represent specific and preferred features of the embodiments of the invention. Features of the dependent claims can be combined with features of the independent and dependent claims, and this in any suitable manner as would be apparent to a person skilled in the art.

The above-mentioned and other features, properties and advantages of the present invention will be clarified with the aid of the following examples of embodiments, optionally in combination with the drawings. The description of these exemplary embodiments is given for clarification, without the intention of limiting the scope of the invention. The reference numerals in the following description refer to the drawings.

Brief description of the figures

Figure 1 is a schematic representation of a Hatschek machine according to the invention.

Description of examples of embodiments

The present invention is described below using specific embodiments.

It should be noted that the term "comprising", as used for example in the claims, may not be interpreted in a limiting sense, limiting to the subsequent elements, features and / or steps. The term "comprising" does not exclude the presence of other elements, features or steps.

So the scope of an expression "an object comprising the elements A and B" is not limited to an object that only contains the elements A and B. The scope of an expression "a method comprising steps A and B" is not limited to a method that only contains steps A and B.

In the light of the present invention, these terms only mean that the relevant elements or steps for the invention are elements A and B, respectively.

In the following specification, reference is made to "an embodiment" or "the embodiment". Such a reference means that a specific element or feature described with reference to this embodiment is included in at least this one embodiment.

However, the occurrence of the terms "in one embodiment" or "in one embodiment" at different places in this description does not necessarily refer to the same embodiment, although it may refer to the same embodiment.

Furthermore, the features or characteristics may be combined in any suitable manner in one or more embodiments, as would be apparent to those skilled in the art.

A Hatschek machine 1000 for manufacturing fiber cement plates is shown in Figure 1. The machine 1000 comprises • a plate making machine 100, • a fiber cement papermaking mixer 200, • a settling vessel 300, • a selectifier 400 and • a premixing unit 500,

A first transport pipe 601 is provided for supplying a first part of the cement-loaded water from the plate making machine 100 to the settling vessel 300.

A second transport pipe 602 is provided for supplying settled cement sludge from settling vessel 300 to selectifier 400.

A third transport pipe 603 is provided for supplying a second part of the cement-loaded water from the plate making machine 100 to the selectifier 400.

These first and third transport pipes 601 and 603 can partly run via shared pipelines 604, which in turn split into the first and third transport pipes 601 and 603.

A fourth transport pipe 605 is provided for supplying cement paste from a fiber cement paste preparation mixer 200 to the selectifier 400. The flow rate of fiber cement paste between the mixer 200 and the selectifier 400 is determined by means of a valve (not shown in Figure 1). This opening of this valve is determined by the thickness of the formed fiber cement plate, and can be adjusted if necessary.

A fifth transport pipe 606 is provided for supplying the hard particles of purified cement mixture from the selectifier 400 to the premixing unit 500.

There is a provision, being a supply 607 for adding flocculant to the premixing unit 500.

A sixth transport pipe 608 is provided for supplying a mixture of the premixing unit 500 to the first vessel 101, the plate making machine 100. The plate making machine 100 also comprises a second vessel 102 and a seventh transport pipe 609 that mix of the premixing unit 500 to this second vessel 102 of the plate making machine 100.

Each of the vessels 101 and 102 has at least one, and as visible in this embodiment, in each case two rotating sieves 103, which in known manner deliver a fine fiber cement film to a conveyor belt 104, which transfers these webs to a forming drum 105.

The Hatschek machine 1000 further comprises a few level meters. It comprises a first level meter 501, being a load cell, for measuring the liquid level in the premixing unit 500 and generating a first measurement signal 701.

The machine 1000 further comprises a second level meter 106 and a third level meter 107 for measuring the liquid level in the first vessel 101 and the second vessel 102, respectively. Each of these level meters generates a measurement signal 702 and 703.

A first control valve 801 is provided for controlling the second part of the cement-loaded water from the plate making machine 100 to the selectifier 400. A second (802) and third (803) control valve is provided for controlling the supply of the amount of the mixture from the premixing unit 500 to the plate making machine 100 via the sixth and seventh transport pipe.

A processing unit 900 is provided for converting the first, second and third measurement signal (701, 702 and 703) to a first, second and third control signal (704, 705 and 706) for controlling the three control valves.

The first control signal 704, which controls the control valve 801, will of course mainly if not only be generated on the basis of the measurement signal 701 of the weighing cell 501. The second control signal 705, which controls the control valve 802, will of course mainly if not only be generated at basis of the measurement signal 702 from the level meter 106 in the first vessel 101. The third control signal 706, which controls the control valve 803, will of course mainly if not only be generated on the basis of the measurement signal 703 from the level meter 107 in the second vessel 102. The level meters 106 and 107 are preferably bubble tubes (also known as bubble tubes).

The machine 1000 further comprises a control valve 804 which controls the permanent supply of a quantity of sludge from the settling vessel 300, also referred to as a decanting unit or cone, to the selectifier. A control valve is a valve whose opening can be controlled but whose opening is not normally changed as a function of a control signal.

When the machine 1000 is in operation, the level in the premixing unit 500 will fluctuate depending on the requested amount of fiber cement pulp via the valves 802 and 803 by the plate making machine 100. These fluctuations are absorbed by more or less cement-laden water via control valve 801 on to the selectifier 400, which in turn flows into the premixing unit 500. This quantity control is done via control signal 704.

As a result of this control, the amount of cement-laden water that is supplied to the settling vessel 300 via transport pipe 601 will vary over time. This while constantly the same amount of sludge from this vessel 300 is supplied via valve 804 to the selectifier. The fluctuations in the supply of cement-laden water will, however, cause little disturbance or hindrance to the stable operation of this settling vessel 300.

If, as in the past, the level of the premixing unit 500 was controlled by supplying sludge or not (and consequently placing the valve 804 either in position open or closed), with a constant supply of cement-laden water via transport pipe 603, the operation of the settling vessel will be disturbed. Such on / off control has a disruptive effect on the flows in the vessel 300.

It is understood that while the embodiments and / or materials for providing embodiments of the present invention have been discussed, various changes or changes may be made without departing from the scope and / or spirit of this invention.

Claims (12)

Claims 1 A method for controlling the liquid level in the premixing unit (500) of a Hatschek machine (1000) comprising a plate making machine (100), a cement papermaking mixer (200), a settling vessel (300), a selectifier (400) and a premixing unit , wherein a first portion of the cement-laden water from the plate making machine is supplied to the settling vessel, and wherein a level meter (501) measures the liquid level in the premixing unit and thereby generates a measurement signal (701) and wherein this measurement signal directly or indirectly control valve (801) controls whereby the amount of the second part of the cement stocked water from the plate making machine fed to the selectifier is controlled. A method according to claim 1 wherein o Sinked cement sludge from the settling vessel is supplied to the selectifier; o Cement paste from a cement paste preparation mixer is supplied to the selectifier; o The cement mixture from the selectifier purified from hard particles is supplied to the premixing unit; o Flocculant is supplied to the premixing unit in order to obtain a mixture which is supplied to the plate making machine. A method according to claim 2, wherein the generated measurement signal is processed by a processing unit (900), which generates a control signal (704) that controls the control valve. A method according to any of claims 2 to 3, wherein the level meter (501) is a load cell. A method according to any of claims 2 to 4, wherein the amount of settled cement sludge from the settling vessel supplied to the selectifier is constant. 6, - A Hatschek machine (1000) for manufacturing fiber cement plates, comprising: • A plate making machine (100), • a cement papermaking mixer (200), • a settling vessel (300), • a selectifier (400) • a premixing unit (500), • a first transport pipe (601) for supplying a first part of the cement-laden water from the plate making machine to the settling vessel; • a second transport pipe (602) for supplying settled cement sludge from the settling vessel to the selectifier; • a third transport pipe (603) for supplying a second part of the cement-loaded water from the plate making machine to the selectifier; A fourth transport pipe (605) for supplying cement paste from a cement paste preparation mixer to the selectifier; • a fifth transport pipe (606) for supplying the hard particles of purified cement mixture from the selectifier to the premixing unit; • a provision for adding flocculant to the premixing unit; • a sixth transport pipe (608) for supplying a mixture from the premixing unit to the plate making machine; • a first level meter (501) for measuring the liquid level in the premixing unit and generating a first measurement signal; A first control valve (801) for controlling the second part of the cement-loaded water from the plate making machine to the selectifier; • a processing unit (900) for converting the first measurement signal (701) to a first control signal (704) for controlling the first control valve. A Hatschek machine according to claim 6, wherein the machine further comprises at least a second control valve (802) for controlling the amount of the premixing unit mixture supplied to the plate making machine via the sixth transport pipe. A Hatschek machine according to any of claims 6 to 7, wherein the plate making machine comprises at least a first vessel (101) in which at least one cylindrical screen (103) is suspended in rotation for the manufacture of a fiber cement web, the sixth transport pipe ( 608) feeds the mixture from the premixing unit to this first vessel of the plate making machine. A Hatschek machine according to claim 8, wherein the first vessel comprises a second level meter (106) for measuring the liquid level in this first vessel and for generating a second measurement signal (702), and wherein the processing unit converts the second measurement signal to a second control signal (706) for controlling the second control valve (803). A Hatschek machine according to any one of claims 6 to 9, wherein the plate making machine comprises at least a second vessel (102) in which at least one cylindrical screen (103) is suspended in rotation for the manufacture of a fiber cement web, wherein a seventh transport pipe ( 609) feeds the mixture from the premixing unit to this second vessel of the plate making machine. A Hatschek machine according to claim 10, wherein the machine further comprises at least a third control valve (802) for controlling the amount of the premixing unit mixture fed to the plate making machine via the seventh transport pipe. A Hatschek machine according to claim 11, wherein the second vessel comprises a third level meter (107) for measuring the liquid level in this second vessel and for generating a third measurement signal (703), and wherein the processing unit the third measurement signal to a third control signal (705) for controlling the third control valve (802).