JP7319714B2 - Plate cylinder cooling device - Google Patents

Description

The present invention relates to a plate cylinder cooling device for cooling a plate cylinder incorporated in a large-sized printing apparatus.

A drum-shaped plate cylinder incorporated in a large-sized high-speed rotary printing machine becomes hot during printing. If the temperature becomes too high, the printing quality deteriorates, so a plate cylinder cooling device is required to keep the plate cylinder at an appropriate temperature. As the plate cylinder cooling device, a water-cooled plate cylinder cooling device with high cooling efficiency can be used. , 2). In such an air-cooled plate cylinder cooling device, a cooling air blowing device is provided along the axial direction of the plate cylinder, and the temperature of the plate cylinder is measured by a temperature sensor. of air to cool. Since the printing press generates a large amount of heat, a large-sized air cooler is required to supply cool air at an appropriate temperature. In such a plate cylinder cooling device, the cooling efficiency is improved by recovering the cold air blown on the surface of the plate cylinder and returning it to the heat exchanger again through the air return duct. can be made smaller.

U.S. Pat. No. 5,309,838 U.S. Pat. No. 5,375,518

The plate cylinder cooling device described above has the following problems. That is, when an air return duct is provided from the printing machine to the cooler, a space for collecting the cool air inside the printing machine and a space for providing the duct are required, which may increase the size of the apparatus.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a plate cylinder cooling apparatus which has a sufficient cooling capacity even if it is an air-cooled type, and does not require a large installation space.

In order to solve the above problems and achieve the object, the plate cylinder cooling device of the present invention is constructed as follows.

A plate cylinder cooling device connected to a cooling passage provided inside a plate cylinder provided in a printing machine for cooling the plate cylinder, comprising: a first cooling water circulation pipe connected to one end of the cooling passage; a second cooling water circulation pipe connected to the other end of the passage; a chamber; a refrigerator arranged in the chamber; a cooling device for taking in outside air and cooling it with the refrigerator , and recooling a part of the cold air with the refrigerator ; and cooling water from the suction side. a heat exchange pipe having one end connected to the suction side of the pump and the other end connected to the first cooling water circulation pipe, and having a heat exchange portion in the middle and a cooling water circulation device comprising a discharge pipe having one end connected to the discharge side of the pump and the other end connected to the second cooling water circulation pipe; and a duct hose that sends the air to the heat exchange section to cool the heat exchange section.

According to the present invention, it is possible to provide a plate cylinder cooling device that has a sufficient cooling capacity even if it is an air-cooled type, and does not require a large installation space.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an explanatory diagram schematically showing a plate cylinder cooling device according to a first embodiment of the present invention; The perspective view which shows the cooling device incorporated in the same plate cylinder cooling device. FIG. 3 is a perspective view showing a blower device incorporated in the plate cylinder cooling device; FIG. 3 is a perspective view showing a jetting device incorporated in the same plate cylinder cooling device; FIG. 5 is an explanatory view schematically showing a plate cylinder cooling device according to a second embodiment of the present invention; The perspective view which shows the cooling part incorporated in the same plate cylinder cooling device. FIG. 9 is an explanatory diagram schematically showing a plate cylinder cooling device according to a third embodiment of the present invention; FIG. 5 is an explanatory diagram schematically showing a plate cylinder cooling device according to a fourth embodiment of the present invention; FIG. 5 is an explanatory view schematically showing a plate cylinder cooling device according to a fifth embodiment of the present invention;

FIG. 1 is an explanatory diagram schematically showing a plate cylinder cooling device 10 according to the first embodiment of the present invention, FIG. 2 is a perspective view showing a cooling device 20 incorporated in the plate cylinder cooling device 10, and FIG. FIG. 4 is a perspective view showing a blower device 30 incorporated in the plate cylinder cooling device 10, and FIG. 4 is a perspective view showing an ejection device 40 incorporated in the plate cylinder cooling device 10. FIG. In the figure, 100 denotes a printing apparatus in which four plate cylinders 110 to be cooled by the plate cylinder cooling device 10 are incorporated, and R denotes cool air. A plate cylinder 110 is provided for each color, and in the case of four-color printing, four units are incorporated into one printing apparatus.

As shown in FIG. 1, the plate cylinder cooling device 10 includes a cooling device 20, four sets of air blowers 30, four sets of ejection devices 40, and duct hoses 50 and 60 connecting them. As shown in FIG. 2, the cooling device 20 includes a cooling circulation chamber box 21 in the shape of a rectangular tube whose axial direction is horizontal. The cooling circulation chamber box 21 is formed by heat insulating plates. One side of the cooling circulation chamber box 21 is closed with a flat lid 22, and the other side is closed with a truncated pyramid-shaped discharge hood 23 narrowing toward the tip. The lid portion 22 is provided with an outside air intake port 22a for taking in outside air. The tip of the discharge hood 23 is provided with four cool air discharge ports 23a. A temperature/anemometer input portion 23b is provided on the side surface of the discharge hood 23 .

Inside the cooling circulation chamber box 21, a refrigerator 24 is suspended so as to be positioned at the center. The refrigerator 24 includes a heat exchanger (evaporator) 24a and a blower fan 24b provided on the outlet side of the heat exchanger 24a. The cooling circulation chamber box 21 has an inlet side area 21 a , an outlet side area 21 b , and an area 21 c between the circumference of the refrigerator 24 and the inner wall of the cooling circulation chamber box 21 .

A duct hose 50 is connected to the cool air discharge port 23a, and is connected to an intake port 32a of a high-pressure blower 32, which will be described later.

As shown in FIG. 3 , the blower device 30 includes a base 31 , a high pressure blower 32 mounted on the base 31 , and an electric valve 33 provided on the outlet side of the high pressure blower 32 . Four high-pressure blowers 32 are provided corresponding to the plate cylinders 110 . The high-pressure blower 32 has an intake port 32a and a discharge port 32b, and a duct hose 50 from the cooling device 20 is connected to the intake port 32a. A duct hose 60 is connected to the discharge port 32b and is connected to a housing 41 which will be described later.

Reference numeral 35 in FIG. 3 denotes a plate cylinder cooling device control panel.

As shown in FIG. 4, the ejection device 40 includes a housing 41 arranged along the axial direction of the plate cylinder 110 , a cooling nozzle 42 provided toward the plate cylinder 110 side of the housing 41 , and a plate cylinder 110 . and a sensor relay box 44 for outputting the output from the radiation temperature sensor 43 as an ON/OFF signal and a proportional current. Incidentally, the radiation temperature sensor 43 and the sensor relay box 44 are provided in one set of the ejection devices 40 among the four sets of ejection devices 40 .

The plate cylinder cooling device 10 configured as described above cools the plate cylinder 110 as follows. In addition, the numerical value shown below is an example. The refrigerator 24 with the target temperature set at, for example, -5°C is operated. As a result, the air existing in the area 21a is cooled and discharged to the area 21b. The amount of air discharged from the refrigerator 24 is, for example, 2700 to 3300 m3/min. The cooled air discharged from the refrigerator 24 returns to the area 21a using the area 21c as a flow path, and is further cooled. By repeating cooling and circulation in this way, the air in the cooling circulation chamber box 21 is lowered to the target temperature preset in the refrigerator 24 . The operation of the refrigerator 24 is controlled independently of the temperature of the plate cylinder 110, and operation, stoppage, defrosting operation, temperature setting, etc. are controlled by a remote controller (not shown).

On the other hand, the temperature of the surface of the plate cylinder 110 is constantly measured by the radiation temperature sensor 43 . When the printing apparatus 100 starts operating, the surface temperature T of the plate cylinder 110 rises. For example, depending on the surface temperature T of the plate cylinder 110 , the electric valve 33 is opened by a predetermined amount via the sensor relay box 44 . For example, the opening degree of the electric valve 33 is as follows. In this example, the valve is fully open when the valve opening is 90°.

In the case of three-stage control, when the surface temperature T is 14°C or higher, the valve opening degree is 90° (flow rate 100%), and when the surface temperature T is 8°C or higher and less than 14°C, the valve opening degree is 70° (flow rate 50%), 8°C When less than 30 degrees of valve opening (flow rate 9%). In the case of proportional control, when the surface temperature T is in the range of 14° to 8°, the valve opening degree is proportionally controlled in the range of 90° to 30° (the flow rate is 100% to 9%). When the surface temperature T is 14° C. or higher, the valve opening degree is 90° (flow rate 100%), and when the surface temperature T is less than 8° C., the valve opening degree is 30° (flow rate 9%).

Cool air R sent by the operation of the high-pressure blower 32 passes through the electric valve 33 and is introduced into the housing 41 via the duct hose 60 . The cool air R introduced into the housing 41 is jetted from the cooling nozzle 42 toward the surface of the plate cylinder 110 . The temperature of the plate cylinder 110 drops as the cold air R is injected, and the surface temperature T also drops.

When the surface temperature T of the plate cylinder 110 decreases, the opening/closing angle of the electric valve 33 decreases, and the rotation frequency of the high-pressure blower 32 decreases based on the surface temperature T and stops. Similarly, the operation of the high-pressure blower 32 and the opening/closing of the electric valve 33 are controlled according to the surface temperature T while the printing apparatus 100 continues to operate.

In this way, according to the plate cylinder cooling device 10 of the present embodiment, the temperature can be lowered to the set temperature by circulating the cold air R in the cooling device 20 . Therefore, even an air-cooled system has a sufficient cooling capacity. In addition, since there is no need to collect cold air from the printing apparatus 100, the installation space can be reduced.

In the above example, only the ON/OFF control of the electric valve 33 may be performed based on the surface temperature of the plate cylinder 110 .

FIG. 5 is an explanatory diagram schematically showing a plate cylinder cooling device 10A according to the second embodiment of the present invention, and FIG. 6 is a perspective view showing a cooling device 70 incorporated in the plate cylinder cooling device 10A. 5 and 6, portions having the same functions as those in FIGS. 1 to 4 are denoted by the same reference numerals, and detailed description thereof will be omitted.

As shown in FIG. 5, the plate cylinder cooling device 10A includes a cooling device 70, a blower device 30, an ejection device 40, and duct hoses 50 and 60 connecting them. As shown in FIG. 6, the cooling device 70 includes a cooling circulation frame 71 in the shape of a rectangular tube whose axial direction is horizontal. A refrigerator 72 is attached to the central portion of the cooling circulation frame 71 .

One side surface of the refrigerator 72 is closed with a flat lid portion 74 , and the other side surface is closed with a cuboid discharge hood 75 . A circulation opening 74a to which the other end of a circulation duct 76, which will be described later, is connected is provided in the center of the lid portion 74, and an outside air intake 74b for taking in outside air is provided around it. The discharge hood 75 has four cold air discharge ports 75a at its tip and an opening 75b on the ceiling side. One end of a circulation duct 76 is connected to the opening 75 b , and the other end is connected to the reflux opening 74 a of the lid 74 .

An air volume adjusting damper 77 is provided in the middle of the circulation duct 76 . The rate of the cool air R to be circulated can be adjusted by the air volume adjustment damper 77 .

A heat exchanger (evaporator) 72 a is provided on the intake side of the refrigerator 72 , and a blower fan 72 b is provided on the outlet side of the refrigerator 72 .

A duct hose 50 is connected to the cool air outlet 75a.

The blower device 30 and jetting device 40 are similar to those of the plate cylinder cooling device 10 described above.

The plate cylinder cooling device 10A configured in this manner cools the plate cylinder 110 as follows. In addition, the numerical value shown below is an example. The air volume adjusting damper 77 is opened, and the refrigerator 72 is operated with the target temperature set at 0° C., for example. The amount of air discharged from the refrigerator 72 is, for example, 2700 to 3300 m3/min. Thereby, cool air R is sent into the discharge hood 75 . A portion of the cold air R is sent through the circulation duct 76 to the reflux opening 74a and cooled again. By repeating cooling and circulation in this way, the air inside the discharge hood 75 is lowered to a temperature preset in the refrigerator 72 .

The cold air R in the discharge hood 75 is sent to the blower device 30 by the operation of the blower fan 72b. Outside air lacking due to air blowing is taken in from the outside air intake port 74 b of the lid portion 74 . The operation of the refrigerator 72 is controlled independently of the temperature of the plate cylinder 110, and operation, stoppage, defrosting operation, temperature setting, etc. are controlled by a remote controller (not shown).

On the other hand, the temperature of the surface of the plate cylinder 110 is constantly measured by the radiation temperature sensor 43 . When the printing apparatus 100 starts operating, the surface temperature T of the plate cylinder 110 rises. For example, depending on the surface temperature T of the plate cylinder 110 , the electric valve 33 is opened by a predetermined amount via the sensor relay box 44 . Also, the inverter 34 drives the high voltage blower 32 at a predetermined rotational frequency.

Cool air R sent by the operation of the high-pressure blower 32 passes through the electric valve 33 and is introduced into the housing 41 via the duct hose 60 . The cool air R introduced into the housing 41 is jetted from the cooling nozzle 42 toward the surface of the plate cylinder 110 . The temperature of the plate cylinder 110 drops as the cold air R is injected, and the surface temperature T also drops.

When the surface temperature T of the plate cylinder 110 decreases, the opening/closing angle of the electric valve 33 decreases and the high pressure blower 32 stops based on the surface temperature T. Similarly, the operation of the high-pressure blower 32 and the opening/closing of the electric valve 33 are controlled according to the surface temperature T while the printing apparatus 100 continues to operate.

In this manner, according to the plate cylinder cooling device 10A according to the present embodiment, the temperature can be lowered to the set temperature by circulating the cold air R in the cooling device 70 . Therefore, even an air-cooled system has a sufficient cooling capacity. In addition, since there is no need to collect cold air from the printing apparatus 100, the installation space can be reduced.

FIG. 7 is an explanatory diagram schematically showing a plate cylinder cooling device 10B according to a third embodiment of the present invention. In FIG. 7, portions having the same functions as those in FIGS. 1 to 6 are denoted by the same reference numerals, and detailed description thereof will be omitted.

As shown in FIG. 7, the plate cylinder cooling device 10B includes two sets of cooling devices 20, a blower device 30, four sets of jetting devices 40, duct hoses 50 and 60 connecting them, and a refrigerating cycle system 80. and a plate cylinder cooling device control panel 90 for cooperatively controlling these parts. A cold air switching solenoid valve 51 is provided in the middle of each duct hose 50 .

The refrigerating cycle system 80 includes a refrigerator 24 that constitutes an evaporator, an outside machine 81 that houses a condenser and the like, a refrigerant liquid line 82 that sends out the refrigerant liquid from the outside machine 81, and from this refrigerant liquid line 82 Refrigerant liquid branch lines 83 for branching and supplying to the two sets of refrigerators 24 respectively, refrigerant gas branch lines 84 for sending out refrigerant gas from the two sets of refrigerators 24, and these refrigerant gas branch lines 84 are collectively stored. and a refrigerant gas line 85 connected to the outer machine 81 .

The refrigerant liquid branch line 83 is provided with an electromagnetic valve 83a. The refrigerant gas branch line 84 is provided with a check valve 84a.

The plate cylinder cooling device control panel 90 incorporates the sensor relay box 44 of the ejection device 40 . It also has a function of switching ON/OFF each of the high-pressure blowers 32, ON/OFF each of the cold air switching solenoid valves 51, and ON/OFF of the solenoid valve 83a.

The plate cylinder cooling device 10B configured in this manner cools the plate cylinder 110 as follows. The high-pressure blower 32 and the outdoor unit 81 are always operated, and the cold air switching electromagnetic valve 51 is closed. One of the two sets of refrigerators 24 is operated and the solenoid valve 83a connected to the refrigerator 24 is opened. As a result, as described above, the cold air R in the refrigerator 24 is lowered to the preset target temperature. Then, the cold air switching electromagnetic valve 51 of the duct 50 connected to the refrigerator 24 is opened.

On the other hand, the temperature of the surface of the plate cylinder 110 is constantly measured by the radiation temperature sensor 43 . When the printing apparatus 100 starts operating, the surface temperature T of the plate cylinder 110 rises. For example, depending on the surface temperature T of the plate cylinder 110 , the electric valve 33 is opened by a predetermined amount via the sensor relay box 44 .

Cool air R sent by the operation of the high-pressure blower 32 passes through the electric valve 33 and is introduced into the housing 41 via the duct hose 60 . The cool air R introduced into the housing 41 is jetted from the cooling nozzle 42 toward the surface of the plate cylinder 110 . The temperature of the plate cylinder 110 drops as the cold air R is injected, and the surface temperature T also drops.

When the surface temperature T of the plate cylinder 110 decreases, the opening/closing angle of the electric valve 33 decreases, and the rotation frequency of the high-pressure blower 32 decreases based on the surface temperature T and stops. Similarly, the operation of the high-pressure blower 32 and the opening/closing of the electric valve 33 are controlled according to the surface temperature T while the printing apparatus 100 continues to operate.

It should be noted that frost may occur inside the refrigerator 24 and the cooling efficiency may decrease. In that case, the electromagnetic valve 83a corresponding to the refrigerator 24 is closed, the other refrigerator 24 of the two sets is operated, and the electromagnetic valve 83a connected to the refrigerator 24 is opened. In this way, one of the refrigerators 24 that has frosted suspends the freezing operation to remove the frost naturally, and the other refrigerator 24 starts the freezing operation to continue cooling the plate cylinder 110 .

Thus, according to the plate cylinder cooling device 10B according to the present embodiment, the same effects as those of the plate cylinder cooling device 10 described above can be obtained. In addition, by alternately operating the two sets of refrigerators 24, the cooling operation of the frosted refrigerators 24 is temporarily stopped, and the defrosting operation can be performed naturally. Therefore, there is no need to stop the printing apparatus 100 .

FIG. 8 is an explanatory view schematically showing a plate cylinder cooling device 200 according to a fourth embodiment of the invention. In addition, in FIG. 8, the same reference numerals are assigned to the same functional parts as in FIG. 1, and detailed description thereof will be omitted.

The plate cylinder cooling device 200 is applied to a water-cooled plate cylinder 500 incorporated in the printing apparatus 400 . The plate cylinder cooling device 200 includes a cooling device 20 , a cooling water circulation device 210 arranged adjacent to the cooling device 20 , and cooling water circulation pipes 220 and 230 connected to the cooling water circulation device 210 .

The cooling water circulation device 210 includes a pump 211, a heat exchange pipe 212 provided on the suction side of the pump 211, and a discharge pipe 213 provided on the discharge side. A cooling water circulation pipe 220 is connected to the discharge pipe 213 . The cooling water circulation pipe 220 is connected to a cooling passage 510 provided inside the plate cylinder 500 .

The heat exchange pipe 212 is provided with a heat exchange portion 212 a in the middle and is cooled by a duct hose 50 extending from the cooling device 20 .

The discharge side of the cooling passage 510 is connected to the cooling water circulation pipe 230 and the heat exchange pipe 212 .

In such a plate cylinder cooling device 200, the plate cylinder 500 is cooled as follows. That is, the pump 211 of the cooling water circulation device 210 is driven to circulate the cooling water through the cooling water circulation pipe 220 , the cooling passage 510 and the cooling water circulation pipe 230 . Also, the cooling device 20 is operated to send cooling air from the duct hose 50 to cool the heat exchange section 212a. By repeating such cooling and circulation, the cooling water is cooled by the cooling device 20, and the plate cylinder 500 is cooled by this cooling water.

In this way, according to the plate cylinder cooling device 200 according to the present embodiment, by using the cold air from the cooling device 20 for cooling the cooling water of the cooling water circulation device 210, which is a cooling device of a water cooling type, the efficiency It can cool well. In addition, since there is no need to collect cold air from the cooling water circulation device 210, the installation space can be reduced.

FIG. 9 is an explanatory view schematically showing a plate cylinder cooling device 200A according to the fifth embodiment of the invention. In addition, in FIG. 9, the same reference numerals are assigned to the same functional parts as in FIG. 8, and detailed description thereof will be omitted.

The plate cylinder cooling device 200</b>A is applied to a water-cooled plate cylinder 500 incorporated in the printing apparatus 400 . The plate cylinder cooling device 200 includes a cooling device 20 , a cooling water circulation device 210 arranged adjacent to the cooling device 20 , and cooling water circulation pipes 220 and 230 connected to the cooling water circulation device 210 .

The cooling water circulation device 210 includes a pump 211, a heat exchange pipe 212 provided on the suction side of the pump 211, and a discharge pipe 213 provided on the discharge side. A cooling water circulation pipe 220 is connected to the discharge pipe 213 . The cooling water circulation pipe 220 is connected to a cooling passage 512 provided inside the plate cylinder 500 .

The heat exchange pipe 212 is provided with a heat exchange portion 212 a in the middle and is cooled by a duct hose 50 extending from the cooling device 20 .

The cooling passage 520 is arranged to reciprocate inside the plate cylinder 500 , and the cooling water circulation pipe 220 and the cooling water circulation pipe 230 are connected to the ends of the plate cylinder 500 on the same side.

The discharge side of the cooling passage 520 is connected to the cooling water circulation pipe 230 and the heat exchange pipe 212 .

In the plate cylinder cooling device 200A, the cooling operation is performed in the same manner as the plate cylinder cooling device 200 described above, and the plate cylinder 500 can be cooled with high efficiency, and the cold air is recovered from the cooling water circulation device 210. Since it is not necessary, the installation space can be reduced.

It should be noted that the present invention is not limited to the above embodiments. For example, in each of the above-described embodiments, the amount of opening and closing of the electric valve 33 is controlled in three stages or proportionally based on the temperature of the surface of the plate cylinder 110, but it may be controlled only by ON/OFF. In addition, it goes without saying that various modifications can be made without departing from the gist of the present invention.
Description equivalent to the invention described in the claims at the time of filing of the present application will be added below.
[1]
In a plate cylinder cooling device for cooling a plate cylinder provided in a printing press,
a cooling device that takes in outside air and cools it, and recools a portion of the cooled outside air;
a fan that accelerates the air cooled by the cooling device;
A plate cylinder cooling device comprising a cooling nozzle for blowing air accelerated by the fan onto the plate cylinder.
[2]
The cooling device includes a chamber, a refrigerator arranged in the chamber, and a return path provided in the chamber for returning part of the cold air discharged from the refrigerator to an inlet side of the refrigerator. The plate cylinder cooling device according to [1], characterized in that
[3]
The cooling device includes a chamber, a refrigerator disposed within the chamber, and a return path provided outside the chamber for partially returning cold air discharged from the refrigerator to an inlet side of the refrigerator. The plate cylinder cooling device according to [1], characterized in that

10, 10A, 200, 200A... Plate cylinder cooling device, 20, 70... Cooling device, 30... Blower device, 40... Ejection device, 42... Cooling nozzle, 100... Printing device, 110... Plate cylinder, R... Cold air.

Claims (2)

In a plate cylinder cooling device connected to a cooling passage provided inside a plate cylinder provided in a printing press and cooling the plate cylinder,
a first cooling water circulation pipe connected to one end of the cooling passage;
a second cooling water circulation pipe connected to the other end of the cooling passage;
A chamber, a refrigerator arranged in the chamber, and a return path provided in the chamber for returning a part of the cold air discharged from the refrigerator to an inlet side of the refrigerator, and taking in outside air. a cooling device that cools by the refrigerator and re-cools a part of the cold air by the refrigerator ;
A pump that sucks cooling water from a suction side and discharges cooling water from a discharge side, one end of which is connected to the suction side of the pump and the other end of which is connected to the first cooling water circulation pipe, and a heat exchange section is provided in an intermediate portion. and a cooling water circulation device comprising a discharge pipe having one end connected to the discharge side of the pump and the other end connected to the second cooling water circulation pipe;
a duct hose that sends the other part of the cold air discharged from the refrigerator to the heat exchange unit to cool the heat exchange unit;
A plate cylinder cooling device. 2. The method of claim 1 , wherein the cooling passage is arranged to reciprocate within the plate cylinder, and the one end and the other end of the cooling passage are arranged at the same side end of the plate cylinder. plate cylinder cooling device.