JP2007160939A - Printing press, especially sheet-fed printing press - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a device for sucking out air flow consisting of the air exhausted from a printing press, especially from the drying device of a sheet-fed printing press or a suitable device for sucking out dust. <P>SOLUTION: The printing press is equipped with a blowing device (14) for providing the predetermined air flow to a flow course (13), in which the flow parts from a material to be printed, especially from a printed sheet or approaches to the material to be printed. A particle filter (16) is assembled in the flow course (13) so as to filter particles, especially fine powder particles off the air flow. In response to the blowing device (14), a controller (17) is provided so as to control the blowing device (14) in order to keep the volume flow rate in the flow course (13) nearly constant even when the filthiness of the particle filter (16) increases due to the particles filtered off the air flow. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The invention relates to a printing machine, in particular a sheet-fed printing machine, according to claim 1.

  A sheet printing machine is used for printing a sheet-like printing material, and such a printing material is also called a printing sheet. Actually known printing presses are equipped with blowers at different locations, and these blowers are identified in the flow path away from or approaching the printed sheet. Used to provide air flow. Thus, for example, a drying device for printed sheets printed on a sheet-fed printing machine is for drying printed printed sheets in a flow path away from the printed printed sheets. It has a blower that produces the warm air flow used. In sheet-fed printing presses known from practice, the volumetric flow rate of such an air flow created via a blower is almost constant, which is actually the constant blower from time to time. This is realized by being driven at a rotational speed of.

  Furthermore, it is known from practice that powder fine particles are sprayed onto a printed sheet printed on a sheet printing machine. In this case, the fine powder particles promote drying of the printed sheet. In this way, when the printed sheet on which the powder particles are sprayed moves through the drying device, the drying device prints the printed sheet via the blower to dry the printed sheet. In order to generate an air flow in the flow path away from the paper, such air flow causes the powder particulates to be drawn into the flow and away from the printed sheet. Such powder particulates are dispersed throughout the printing factory without interruption. If a worker in a printing factory inhales such fine powder particles, it may result in a health hazard.

  This problem is also seen in the case of other air flows generated via the blower in a sheet-fed printing press. Furthermore, the same phenomenon can be confirmed in the roll paper printer.

  In view of the circumstances as described above, it is an object of the present invention to provide a novel printing machine, particularly a novel sheet-fed printing machine.

  The above-described problem is solved by a printing machine according to claim 1. In the present invention, a particle filter is incorporated in the flow path, whereby particles, particularly powder particulates, are filtered from the air flow, and the air blower is provided with a control device corresponding thereto. The rotational speed of the blower is controlled so that the volumetric flow rate in the flow path is maintained constant even when the dirt of the particle filter is increased due to particles filtered from the air flow.

  According to the present invention, a particle filter is incorporated in a flow path in which a predetermined air flow is created via the blower, and thereby particles are filtered from the air flow.

  The application of the present invention can be carried out in a device for sucking out a flow of air consisting of air discharged from a drying device or a device for sucking out powder.

  By applying the present invention, for example, powder fine particles are prevented from being sprayed unimpeded in a printing factory. Further, a control device is provided corresponding to the blower, and the control device is provided in the flow path even when the dirt of the particle filter is increased due to particles filtered from the air flow. The rotational speed of the blower is controlled so that the volume flow rate is maintained substantially constant. As described above, the present invention is made based on the following recognition. That is, when the particle filter is incorporated in the flow path that guides the air flow, the flow resistance in the flow path is not constant, so that the rotation of the blower incorporated in the flow path is maintained in order to maintain the volume flow rate substantially constant. The recognition is that the number must be controlled.

  It is preferable that a sensor is provided corresponding to the flow path. This sensor measures the pressure occupying the flow path or the volume flow rate occupying the flow path on the downstream side of the particle filter, and the control device controls the rotation speed of the blower based on the corresponding measurement value.

  According to a preferred configuration of the present invention, the control device checks whether or not the rotational speed for the blower set based on the control exceeds the allowable maximum rotational speed. If the rotation speed for the blower set based on the control exceeds the maximum allowable rotation speed, the control device automatically sends a message for maintenance or replacement of the particle filter. Generate.

  In addition, the controller checks whether the volume flow determined based on the control is below an acceptable minimum volume flow. If the volume flow determined based on the control is below the allowable minimum volume flow, the control device automatically creates an alarm and / or automatically stops the printing press.

  Further preferred configurations of the invention are described in the dependent claims and in the following description. Although one embodiment of the present invention is described in detail below based on a drawing, the present invention is not limited to this embodiment.

  Hereinafter, the present invention will be described in detail with reference to FIG.

  FIG. 1 is a partial view showing a very schematic area of a drying device 10 of a sheet-fed printing press according to the present invention. The drying device is used to dry the printed sheet 11 printed on the sheet printer. The printed sheet moves through the drying device 10 in the direction of arrow 12.

  The drying device 10 has a blower device 14 incorporated in the flow path 13. The blower 14 generates a flow of air away from the printed printed sheet 11 in the flow path 13 of the drying device 10, that is, a flow of warm air. The direction of flow in the flow path 13 is illustrated by arrows 15.

  A particle filter 16 is further incorporated in the flow path 13. The particle filter 16 is used to filter the particles from the air flow generated via the blower 14, and in particular to promote the drying of the printing sheet 11 in the sheet printing machine. Used to filter powder particles sprayed on the surface.

  When the flow resistance in the flow path 13 increases when the dirt of the particle filter 16 increases due to particles filtered from the air flow, the rotational speed of the blower 14 is constant. In a state, a constant volume flow cannot be maintained in the flow path 13.

  In view of this problem, in the present invention, the air blower 14 is provided with a control device 17 corresponding thereto. This control device controls the rotation speed of the blower 14 so that the volume flow rate in the flow path 13 remains substantially constant even if the dirt of the particle filter 16 increases.

  In FIG. 1, a sensor 18 is provided corresponding to the flow path 13. This sensor measures the pressure in the flow path 13 or the volume flow rate in the flow path on the downstream side of the particle filter 16 as viewed in the flow direction (arrow 15), and the measurement signal 19 corresponding to the pressure or volume flow rate. Is transmitted to the control device 17 as an actual value. Measurement of the pressure occupying the flow path 13 is preferable to measurement of the volume flow rate. The reason is that the measurement of pressure can be performed more easily and more advantageously in terms of cost. For example, by means of a characteristic curve, the volume flow rate occupying the flow path 13 can be derived easily and quickly based on the pressure occupying the flow path 13.

  The actual value provided by the sensor 18 is compared with the target value in the controller 17. At that time, if a difference is found between the actual value and the target value, the control device detects the changed rotation speed for the blower device as the operation signal 20 for the blower device 14. In accordance with this rotational speed, a predetermined volume flow rate in the flow path 13 is maintained, and can thus be kept substantially constant. For example, when the volume flow rate in the flow path decreases due to an increase in the contamination of the particle filter 16, the control device 17 increases the rotational speed of the blower device 14, and as a result, the volume flow rate can be kept constant. .

  While the rotational speed of the blower is controlled as described above, it is continuously determined whether the rotational speed for the blower set based on the control by the control device 17 exceeds the allowable maximum rotational speed. Inspected. If the rotational speed for the blower set based on the control exceeds the allowable maximum rotational speed, the control device 17 automatically creates a message 21 and based on this message, the particle filter 16 Maintenance inspection or replacement is performed. This message 21 can be visualized on the display device 22, for example.

  Furthermore, during control, the control device 17 checks whether the volume flow determined based on the control is below the minimum allowable volume flow.

  If the volume flow determined based on the control is below the minimum allowable volume flow, the controller automatically generates an alarm 23. This alarm can be visualized on the display device 24 as well. Further, in this case, the printing press can be automatically stopped. That is, when the actual volume flow is below the minimum allowable volume flow, the required drying rate is no longer guaranteed by the drying apparatus 10 in the illustrated embodiment.

  As described above, the present invention is not limited to use with a drying device of a sheet-fed printing press. The present invention can be used anywhere on a printing press or in a printing press as long as the particle filter is to be incorporated in a flow path in which an air flow is generated via a blower.

  The application of the present invention can preferably be carried out especially for the purpose of sucking off excess powder using an air flow from the sheet transport area of the printing device to the sheet discharge machine of the printing press. Powder suck-out remains constant during continuous operation. The reason is that the powder is certainly sprayed in a metered state, but in the sheet transport area, it swirls strongly and is partially scattered in a relatively large printing press area. Therefore, in order to remove excess powder, a constant high suction rate (Absaugleistung) is required here as well. According to the invention, this requirement can be met efficiently by means already described above of the device for powder suction of the sheet discharger of the printing press.

  The present invention can be applied to both a sheet-fed paper printer and a roll paper printer.

1 is a block diagram showing the main components of the present invention of a printing press according to the present invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Drying device 11 Print sheet 12 Conveyance direction 13 Flow path 14 Blower device 15 Flow direction 16 Particle filter 17 Controller 18 Sensor 19 Measurement signal 20 Operation signal 21 Message 22 Display device 23 Alarm 24 Display device

Claims (5)

A printing machine, especially a sheet-fed printing machine,
A blower device (14) for providing a predetermined air flow in a flow path (13) away from or towards the printed material, in particular the printed sheet,
In particular, the flow of air in the drying device is used in printing machines, in particular sheet-fed printing machines, used for drying printed materials, in particular printed printing sheets.
The flow path (13) incorporates a particle filter (16), thereby filtering particles, in particular powder particulates, from the air stream,
The air blower (14) is provided with a control device (17), and the control device increases the contamination of the particle filter (16) due to particles filtered from the air flow. A printing machine, particularly a sheet-fed printing machine, that controls the blower (14) so that the volume flow rate in the flow path (13) remains substantially constant even if A printing machine, especially a sheet-fed printing machine,
A blower device (14) for providing a predetermined air flow in a flow path (13) away from or towards the printed material, in particular the printed sheet,
In particular, the air flow in the suction device in the transport path of the printed material, in particular the printed printing sheet, is after the last printing device in the transport path to the sheet discharge machine. In a printing machine, especially a sheet-fed printing machine, used for sucking powder in the area of
A particle filter (16) is provided in connection with the flow path (13), thereby filtering powder particulates from the air stream,
The air blower (14) is provided with a control device (17), and the control device increases the contamination of the particle filter (16) due to powder particles filtered from the air flow. The printing apparatus, particularly a sheet, characterized in that the blower (14) is controlled so that the volume flow rate in the flow path (13) remains substantially constant even when Printer. The printing press according to claim 1 or 2,
A sensor (18) is provided corresponding to the flow path (13), and the sensor measures the pressure or volume capacity occupying the flow path on the downstream side of the particle filter (16). In this case, the control device controls the number of rotations of the blower (14) based on the corresponding measurement value. The printing press according to any one of claims 1 to 3,
The control device (17) checks whether or not the rotational speed for the blower (14) specified based on the control exceeds an allowable maximum rotational speed, and if so, The printing machine, wherein the control device (17) automatically generates a message (21) for maintenance or replacement of the particle filter (16). The printing press according to any one of claims 1 to 4,
The control device (17) checks whether the volume capacity determined based on the control is below an allowable minimum volume capacity, and if so, the control device (17)
A printing machine, characterized in that the alarm (23) is automatically created and / or the printing machine is automatically stopped.

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