JP5041849B2 - Exhaust temperature control system for pneumatic equipment station - Google Patents

Description

  The present invention relates to an exhaust temperature adjustment system for a pneumatic device station that houses a pneumatic device that generates negative or positive air pressure, such as a vacuum pump or a blower, and an air conditioning system in a factory room.

  Conventionally, pneumatic devices such as vacuum pumps and blowers are heavy and are individually installed on the floor in a factory. In addition, these pneumatic devices generate heat by having a function of compressing air. For this reason, the pneumatic device is generally installed without surrounding so that heat is dissipated.

On the other hand, these pneumatic devices generate noise when the air is depressurized or pressurized.
On the other hand, the present applicant has proposed a soundproof box having a double structure that individually stores heating elements such as vacuum pumps (see Patent Document 1 and Patent Document 2).
According to this soundproof box, gas is forcibly circulated by a blower fan between the inside of the soundproof box and the double-structured wall to cool it, and a sound absorbing material is applied along the inner surface of the wall. Soundproof. Moreover, in the soundproof box of patent document 2, since it comprised so that it might spray, after dividing the flow of cooling air into two directions equally, an apparatus can be cooled uniformly.
Japanese Utility Model Publication No. 63-22000 (first page, FIG. 1) Japanese Utility Model Publication No. 5-42480 (first page, FIG. 1)

The problems to be solved with regard to the exhaust temperature control system of the pneumatic equipment station are conventionally limited to those which can suitably store objects to be stored such as a vacuum pump and a blower which generate heat, but those which are described in the background art section. Generally, this is because it has not been proposed.
Air that has cooled a heating element such as a vacuum pump or a blower in the pneumatic device station is discharged into the factory room or discharged outside the room through a duct. However, conventionally, there is almost no technical idea of storing a plurality of heavy objects to be stored in a box, and no proposal has been made for using the exhaust (heat exhaust etc.).

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to exhaust a pneumatic device station that can favorably assist air conditioning in a factory room by using exhaust from a pneumatic device station in which stored objects such as a vacuum pump and a blower that generate heat are stored. It is to provide a temperature control system.

The present invention has the following configuration in order to achieve the above object.
According to one embodiment of the exhaust temperature conditioning system of the air pressure system stations according to the present invention, a pneumatic device to produce a negative pressure and positive pressure air such as a vacuum pump or blower, Rutotomoni closed space can more accommodating the air pressure device a storage box that can be soundproofed be accommodated in, the air pressure the storage box that is heated by the device, to cool incorporating external air, cooling air flow from a substantially downwardly within the storage box upwardly A blower that generates and exhausts air, a water-cooled cooler that is provided to pass the cooling air flow and cool, a cooler unit that supplies cold water to the cooler, and a supply to the cooler At least a water temperature control means for controlling the water temperature so as to adjust the temperature of the cold water and a flow rate control means for controlling the flow rate so as to adjust the flow rate of the cold water supplied to the cooler. One is provided, et al is, the flow of the storage shelf-like supporting portion in which the air pressure device to the intermediate portion is placed in the height direction in the box is provided at least one stage, the shelf-like support portion is the cooling air flow It is characterized by having an open part so as to allow .
Moreover, according to one form of the exhaust temperature adjustment system of the pneumatic device station concerning this invention, it is the said pneumatic device above the position in which each pneumatic device in the flow path of the said cooling airflow is mounted. An exhaust port of an exhaust pipe for guiding and exhausting heated air from the vacuum pump device is opened, and a mixing space is provided to be mixed with the heated air exhausted from the exhaust port when the cooling air flows from the bottom to the top It can be characterized by being.

Also, according to an embodiment of the exhaust temperature conditioning system of the air pressure system stations according to the present invention, the water temperature control means, the temperature of the cooler unit based on detection data by the water temperature detecting device for detecting a temperature of the cooling water It can be characterized by controlling.

Also, according to an embodiment of the exhaust temperature conditioning system of the air pressure system stations according to the present invention, the flow control means adjusts the opening and closing of the control valve based on detection data by the flow rate detection device for detecting the flow rate of the cooling water Thus, the flow rate can be controlled.

  Further, according to one aspect of the air conditioning system in the factory room according to the present invention, the air conditioner is installed for the purpose of functioning as a general air conditioner provided to perform air conditioning in the factory room and an air conditioner auxiliary device in the factory room. And an exhaust temperature adjusting system for the pneumatic device station.

  Moreover, according to one form of the air conditioning system in the factory room concerning this invention, the said factory can be characterized by being a printing factory which needs management of indoor temperature and humidity.

  According to the exhaust temperature control system for a pneumatic equipment station according to the present invention, air conditioning in a factory room is suitably assisted by using exhaust from a pneumatic equipment station in which stored objects such as a vacuum pump and a blower that generate heat are stored. It has a particularly advantageous effect of being able to.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, a best mode example of a pneumatic device station including an exhaust temperature adjusting system according to the present invention will be described in detail based on the attached drawings (FIGS. 1 to 20).
FIG. 1 is a perspective view conceptually illustrating a pneumatic device station according to the present invention.
FIG. 1 shows a pneumatic device station in which the shelf-like support portions 30 on which the pneumatic device 10 is placed are provided in a plurality of stages.
The pneumatic device 10 is a device that generates negative or positive air pressure such as a vacuum pump or a blower, and includes a compressor device.
The configuration of the pneumatic device station excluding the pneumatic device 10 is a storage box for the pneumatic device.

A storage box 20 stores a plurality of pneumatic devices 10 and is soundproofed by storing them in a closed space. It is a rectangular box and has a structure in which the front (front) is opened. In this embodiment, a pair of doors 22 and 22 that are opened in a double door is provided.
Reference numeral 40 denotes a blower that generates a cooling air flow that flows in one direction from the lower side to the upper side in the storage box 20 in order to cool the storage box 20 heated by the pneumatic device 10. In this embodiment, an axial fan (a pressure ventilation fan) is employed.

A sound absorbing material 24 is provided on the inner surface of the wall portion of the storage box 20. The inner surface of the wall portion is a surface inside at least the side wall constituting the storage box 20 and includes the inner surface of the door 22. That is, it is only necessary to improve the soundproofing performance by disposing the sound absorbing material 24 in as many portions as possible while targeting the inner surface of the portion that does not affect the flow of the cooling airflow.
As the sound absorbing material 24, a sheet-like member having a predetermined thickness made of a sponge-like resin material can be employed. The sound absorbing material 24 may be fixed by adhesion or separate attachment means so as to cover the inner surface of the wall portion. Of course, other forms of the sound absorbing material 24 may be used with other materials such as rubber as long as they can be incorporated into the wall of the storage box 20.

The storage box 20 is provided with at least one shelf-like support 30 on which the pneumatic device 10 is placed in the middle in the height direction. In this embodiment, a three-stage shelf-like support portion 30 is provided. And the shelf-like support part 30 has an open part 31 so as to allow the flow of the cooling air flow.
Thus, the plurality of pneumatic devices 10 can be suitably accommodated three-dimensionally by the plurality of stages of the shelf-like support portions 30. Therefore, the installation space can be reduced.
Moreover, since the shelf-shaped support part 30 has the open part 31, cooling air flows smoothly and the inside of the storage box 20 can be cooled suitably. Moreover, ventilation resistance can be suppressed low and the burden of the air blower 40 can be reduced.

The blower 40 is provided above the position where each pneumatic device 10 is placed so as to suck air from below and discharge it upward.
Thereby, the flow of the cooling air in one direction from the bottom to the top can be suitably generated together with the rising airflow of the air heated by each pneumatic device 10. That is, it is possible to efficiently blow air by matching the convection phenomenon with the air flow by the blower 40.
In addition, each component including components to be described later is arranged in series, and there are few elements that obstruct the cooling air flow, and there is an effect that the blower loss of the blower 40 is small.

Reference numeral 50 denotes a cooling means, which is provided above the position where each pneumatic device 10 is placed in the flow path of the cooling air flow, and cools the air heated by the heat generated by the pneumatic device 10. Thereby, even if it exhausts indoors, indoor temperature can be maintained suitably, without raising indoor temperature.
The cooling means 50 is disposed below the blower 40 in the flow path of the cooling airflow. That is, it is arranged leeward from each pneumatic device 10 and leeward from the blower 40. Thereby, the air blower 40 is not heated, and the occurrence of the malfunction of the air blower 40 due to overheating can be prevented.

The cooling means 50 can be a water-cooled cooler 50a (see FIGS. 14 to 17). Cooling water supplied by a dedicated cooler unit or cooling water prepared in the factory can be suitably used.
According to the water-cooled cooler 50a, the degree of cooling (temperature) of the discharged air can be appropriately adjusted by changing the amount of water and the water temperature. Conventionally, the generated heat is removed by air conditioning. However, since industrial water can be used, the running cost is greatly reduced.

Reference numeral 11 denotes a hose, which is provided to supply pressurized air from the pneumatic device 10 to an external working device, and supplies decompressed air so that air is sucked from the external working device by the pneumatic device 10. There is something that is provided to do.
Reference numeral 12 denotes a connection port, to which the hose 11 is connected from the inside, and is disposed at the lower part of the front surface of the storage box 20. Via this connection port 12, the hose 11 connected to each pneumatic device 10 can be connected to a working device that performs work using air pressure outside. The connection port 12 may be disposed on the rear surface of the storage box 20.

And these hoses 11 are piped so that it may pass below the position where each pneumatic apparatus 10 in the flow path of the cooling air flow is placed.
Thereby, especially the heated pressurized air at the time of supplying the pressurized air from the pneumatic apparatus 10 to an external apparatus can be cooled. It becomes an aftercooler of the pneumatic device 10 and can discharge suitable pressurized air.
The arrangement position of the connection port 12 is not limited to the front surface of the storage box 20 and may be the rear surface of the storage box 20.

Next, an exhaust temperature adjustment system of a pneumatic device station (hereinafter sometimes referred to as “air station”) will be described with reference to FIGS. 2 and 3. FIG. 2 is a block diagram of an exhaust temperature adjustment system of a pneumatic equipment station, and FIG. 3 is an explanatory diagram showing a flow of a cooling step.
According to the exhaust temperature adjustment system of this pneumatic equipment station (air station 1), the water temperature control means for controlling the water temperature so as to adjust the temperature of the cold water supplied to the cooler 50a (see FIG. 14 etc.) of the air station 1; At least one of flow rate control means for controlling the flow rate so as to adjust the flow rate of the cold water supplied to the cooler 50a is provided.

As shown in FIGS. 2 and 3, reference numeral 2 denotes a cooler unit, which is provided outside the factory room so as to supply cold water to the cooler 50a.
3 is a valve on the water supply flow path side, and 4 is a valve on the return flow path side. 6 is a flow meter, and 7 is a water temperature meter. Further, 5 is a bypass valve, and the flow rate can be controlled by short-circuiting the supply of the cooling water when the cooling water is not allowed to flow to the air station 1.

FIG. 4 is a graph showing the temperature change of the exhaust gas that has passed through the cooler 50a (condenser) with respect to the temperature change of the cooling water, with the ambient temperature and the flow rate of the cooling water being constant, and the horizontal axis is the temperature of the cooling water (° C.). The vertical axis represents the exhaust gas temperature (° C.).
According to this graph, it can be seen that as the temperature of the cooling water rises, the temperature of the exhaust also rises linearly proportionally. For this reason, from this graph, the temperature of the exhaust can be easily predicted by the temperature of the cooling water. And the change of the indoor temperature from which the exhaust is discharged can also be predicted.
Therefore, according to the water temperature control means, the exhaust temperature and the room temperature of the air station 1 can be appropriately controlled.

The temperature (water temperature) of the cooling water supplied by the cooler unit 2 is detected by a water temperature detection device (water temperature gauge 7), and the water temperature is controlled by a water temperature control means (not shown) according to the exhaust temperature and room temperature conditions. Thus, the exhaust temperature and the room temperature can be adjusted. That is, according to the exhaust temperature adjustment system of this pneumatic device station, it can be suitably used as an auxiliary means for indoor air conditioning.
The water temperature control means may be operated by computer control such as manual control or feedback control, and the operation method is not particularly limited.
Further, the water temperature control means may be controlled based on sensor detection data other than the water temperature such as the flow rate of the cooling water and the room temperature.

FIG. 5 is a graph showing a change in the temperature of the exhaust gas that has passed through the cooler 50a (condenser) with respect to a change in the flow rate of the cooling water, with the ambient temperature and the temperature of the cooling water being constant. min.), and the vertical axis represents the exhaust gas temperature (° C.).
According to this graph, it can be seen that as the flow rate of the cooling water increases, the temperature of the exhaust gas decreases linearly in proportion. For this reason, from this graph, the exhaust temperature can be easily predicted by the flow rate of the cooling water. And the change of the indoor temperature from which the exhaust is discharged can also be predicted.
Therefore, according to the flow rate control means, the exhaust temperature and the room temperature of the air station 1 can be appropriately controlled.

The flow rate of the cooling water supplied by the cooler unit 2 is detected by a flow rate detection device (flow meter 6), and the flow rate is controlled by the flow rate control means according to the exhaust temperature and the room temperature, so that the exhaust gas temperature and the room temperature. Can be adjusted. That is, according to the exhaust temperature adjustment system of this pneumatic device station, it can be suitably used as an auxiliary means for indoor air conditioning.
This flow rate control means can be constituted by a control valve (water amount control valves 3, 4, 5) such as an electromagnetic valve provided in the cooling water flow path 8.
The flow rate control means may be operated by computer program control such as manual control or feedback control, and the operation method is not particularly limited.
Further, the flow rate control means may be controlled based on sensor detection data other than the flow rate such as the temperature of the cooling water and the room temperature.

FIG. 6 is a graph showing the temperature change of the exhaust gas that has passed through the cooler 50a (condenser) when the load of the pneumatic device changes. The horizontal axis shows the load change (kw) of the pneumatic device, and the vertical axis shows the exhaust temperature ( ° C). When the temperature and flow rate of the cooling water are constant, the exhaust temperature rises linearly in proportion to the increase in the overall load of the pneumatic device built in the pneumatic device station.
Therefore, the temperature of the exhaust gas may be controlled by appropriately changing the temperature and flow rate of the cooling water in response to a load change of the pneumatic device.

According to the exhaust temperature adjustment system of the pneumatic device station configured as described above, the general air conditioner provided to perform air conditioning in the factory room also functions as an auxiliary device for air conditioning in the factory room. Can be installed at. That is, it can be suitably used as part of an air conditioning system in a factory room.
This is particularly effective in a printing factory that requires management of indoor temperature and humidity.

For example, a dry pump and a blower built in a water-cooled pneumatic device station are used as negative pressure sources for paper adsorption and feeding and as positive pressure sources for paper separation in a printing factory.
The printing environment generally ideal in the printing factory has an air temperature of 25 ° C. and a humidity of 55%. On the other hand, according to the water-cooled pneumatic apparatus station of this embodiment, heat is exchanged with the exhaust heat of the pump and blower using water as a medium. Yes.
Therefore, it is not necessary to exhaust the exhaust to the outside through a duct, heat exchange is performed locally and efficiently, and a large blower as in the case of air cooling is not required, so that exhaust heat can be efficiently processed.

And by stopping the flow of the cooling water or raising the water temperature, the temperature of the exhaust can be raised and the exhaust heat can be used, which can be used as heating in the factory room. Although it depends on the load of the pneumatic device, when the room temperature is 25 ° C., warm air of 30 to 45 ° C. can be discharged and supplied indoors.
Further, by reducing the water temperature or increasing the flow rate of the cooling water, the cooling air (cold air) can be discharged and supplied indoors. That is, it can be used for cooling.
By using such an air conditioning function together with a general air conditioner in a factory room, it is possible to construct an air conditioning system with high energy efficiency as a whole.

Next, the best embodiment of the shelf-like structure and the pneumatic device storage box according to the present invention will be described in detail with reference to the accompanying drawings (FIGS. 7 to 12).
FIG. 7 is a perspective view for explaining one embodiment of the shelf-like support portion of the storage box according to the present invention. FIG. 8 is a plan view showing an example of a ladder, FIG. 9 is a side view showing an example of the ladder, and FIG. 10 is a front view showing an example of the ladder. FIG. 11 is a perspective view for explaining the framework of the entire rack structure of the storage box. Further, FIG. 12 is a perspective view for explaining a structure in which the shelf-like support portion is supported by a support column constituting the storage box.

The storage box 20 includes a shelf-like support portion 30 on which the storage objects are placed so that a plurality of storage objects such as a vacuum pump and a blower can be three-dimensionally stored. It is a rectangular parallelepiped box 21 (see FIG. 1 and FIG. 11 etc.).
Further, the box body 21 has a shelf-like structure constituted by a rectangular parallelepiped frame provided with a shelf-like support portion 30 on which an article to be stored is placed, and the periphery of the rectangular parallelepiped frame is a wall material. The front is provided in a box shape that can be opened and closed.
In this embodiment, the object to be stored is the pneumatic device 10, which is a storage box used for the pneumatic device station.

  The shelf-like support part 30 is arranged at the front part and the rear part of the box body 21 and extends in the front-rear direction so as to be bridged between the pair of beams 60, 60 extending horizontally and horizontally. It is provided with a ladder 70 that is a transfer member provided in a width that creates a gap that allows the flow of air in the vertical direction in both the left and right directions and on which an object (pneumatic device 10) is placed.

The beam 60 is constituted by an upper and lower horizontal plate portions 61a and 62a and a vertical plate portion 63 which is a portion integrally connecting the upper and lower horizontal plate portions 61a and 62a so as to have two horizontal planes 61 and 62 in a different level. It is provided in steps.
Further, the beam 60 is disposed in the box body 21 so that the upper horizontal surface 61 is located outside and the lower horizontal surface 62 is located inside.

  The ladder 70 has an upper surface 71 provided on an entirely flat horizontal surface, and extended flat plate portions 73 that are respectively extended in a flat plate shape at both ends of the upper surface 71 and are received by the horizontal surface 61 on the upper side of the beam 60. Prepare. Further, the ladder 70 is provided so that both end portions of the lower surface portion 72 are received by the horizontal surface 62 below the beam 60.

According to the shelf-like support portion 30 including the beam 60 and the ladder 70 as described above, the entire upper surface of the ladder 70 becomes a flat horizontal surface, and the pneumatic device 10 can be easily put in and out at the time of attachment work or replacement work. Also, when performing maintenance and management of the pneumatic device 10, the entire upper surface is flat and there is no obstructing part, so that the operation is easy.
The ladder 70 is received and supported by both the upper horizontal surface 61 and the lower horizontal surface 62 of the beam 60. For this reason, load bearing strength can be secured and the pneumatic device 10 which is a heavy object can be suitably supported.
This effect is produced only by the shelf-like structure configured by the rectangular parallelepiped frame having the shelf-like support portion 30 on which the objects are placed. The structure can be applied as a shelf-like structure for storing other heavy equipment.

Further, the upper surface portion 71 of the ladder 70 is provided with elongated holes 78 for attaching the objects to be stored in two rows in the left-right direction and long in the front-rear direction. In addition, a plurality of elongated holes 78 for mounting the objects to be stored are provided intermittently in the front-rear direction, which is the longitudinal direction of the ladder 70.
Using the elongated holes 78 for mounting the stored objects, the stored objects are fixed to the ladder 70 by fixing means such as bolts and nuts.
Thus, by providing the elongated holes 78 for mounting the objects to be stored, the degree of freedom for mounting the pneumatic device 10 and the like is greatly improved in both the left-right direction and the front-rear direction.
Accordingly, various objects to be stored such as the pneumatic device 10 can be freely arranged and stored in the storage box 20, and the commonality and versatility can be improved. For example, it is possible to flexibly cope with a change in the pump or blower to be installed due to specification changes or new additions.

Next, a structure for attaching the ladder 70 to the beam 60 will be described.
In order to fix the ladder 70 to the beam 60 by tightening the male screw 35 from the outside of the box body 21, through holes 65 are provided in the standing plate portion 63 of the beam 60, and both ends of the ladder 70 are extended plate portions. A female screw portion 75 is provided below 73.
In this embodiment, the male screw 35 is a bolt and the female screw portion 75 is a projection nut.
Moreover, the through-hole 65 opened to the standing plate part 63 is provided in the long hole long in the left-right direction. According to this, position adjustment in the left-right direction (see the arrow in FIG. 7) is possible, and the ladder 70 can be easily fixed at a desired position.

The beam 60 can be formed by bending a metal plate material in a step shape. Note that the staircase shape has a shape that can be expressed as a cross-sectional crank shape or a cross-sectional saddle shape as is apparent from FIG.
The ladder 70 is formed of a metal plate bent into a U-shaped cross section with an open lower surface, and end surfaces 77 formed at both ends of the ladder 70 and below the extended flat plate 73 are formed of a metal member. The side plate portion 74 is formed by bending inward. A through hole is opened in the end surface portion 77, and a projection nut (female screw portion 75) is welded to the back side thereof.
As described above, the beam 60 and the ladder 70 can be easily manufactured because they can be formed by bending a metal plate.
Moreover, the part 74a except the both ends of the side-plate part 74 becomes a form where the lower side was notched, and has enlarged the mounting space for a to-be-contained thing. Reference numeral 74b denotes a small hole, which is used for mounting a bracket or the like for fixing the wiring.

Further, in this embodiment, both ends of the pair of beams 60, 60 are respectively arranged on both side portions of the box body 21 in the left-right direction, and are horizontally attached to the pair of side beams 80, 80 extending in the front-rear direction. It is fixed by fixing means including 82. The pair of side beams 80 and 80 are fixed to the four support columns 25 constituting the box body 21, so that the shelf-like support portion 30 is provided at a desired height position in the box body 21. Yes. The height position of the shelf-like support portion 30 is adjusted by fixing the side beam 80 to the support column by fixing means including a plurality of mounting holes 25a provided at predetermined intervals in the height direction of the support column 25 and bolts 81. This is done by fixing at 25 desired height positions.
According to this, the shelf-like support portion 30 constituted by the rectangular frame 33 is formed by the pair of beams 60 and 60 and the pair of side beams 80 and 80, and the strength of the box body 21. Can be improved. Therefore, it is possible to favorably support the item to be stored.

According to the pneumatic device storage box 20 described above, since the ladder 70 can be arranged so as to be simply placed on the pair of beams 60, 60, it can be easily attached.
In addition, vacuum pumps, blowers, and the like require periodic replacement of consumable parts such as blades and bearings, and in that case, they must be removed from the installation site. According to the pneumatic device storage box 20 of the present embodiment, as described above, since the upper surface of the ladder 70 of the shelf-like support 30 is flat, such an operation can be easily performed by using a normal lifter. Can do.

  The shelf structure and the storage box 20 used in the pneumatic device 10 have been described above, but the present invention is not limited to this, and can be suitably applied when storing other objects to be stored, particularly heavy objects. .

Next, based on FIGS. 13-17, the process of the heating air exhausted from the pneumatic apparatus 10 of a pneumatic apparatus station is demonstrated.
FIG. 13 is a front view for explaining the arrangement of the pneumatic devices 10 in the storage box 20 and the piping. 14 to 17 are side views for explaining the arrangement and piping of the specific pneumatic device 10 in the storage box 20.

As shown in FIG. 13, reference numeral 13 denotes an exhaust pipe, which is a pipe line that guides and exhausts high-temperature heated air to be discarded from each pneumatic apparatus 10. An exhaust port of the exhaust pipe 13 is provided above the position where each pneumatic device 10 is placed in the flow path of the cooling air flow and below the cooling means 50.
Thus, the problem which generate | occur | produces when the pneumatic apparatus 10 is overheated can be prevented by exhausting heated air above the position where each pneumatic apparatus 10 was mounted. In particular, the life of the bearing used in each pneumatic device 10 can be greatly extended, and running costs (particularly maintenance costs) can be reduced.

Hereinafter, the piping concerning the specific pneumatic apparatus 10 is demonstrated in detail based on FIGS.
FIG. 14 is a view taken in the direction of the arrow A in FIG. 13 and shows the piping (vacuum suction piping and heating air exhaust piping) of the vacuum pump device 10a that generates a decompression that sucks air from the air working device. . In addition, the arrow in a figure has shown the flow of air.
The hose 11a is a pipe that sucks air from an external air working device by the vacuum pump device 10a. The lower portion of the hose 11a is piped so as to pass substantially horizontally below the position where each pneumatic device 10 is placed in the flow path of the cooling airflow.
Further, the exhaust pipe 13a is a pipe line that guides and exhausts high-temperature heated air to be discarded from the vacuum pump device 10a.

The exhaust port 15a of the exhaust pipe 13a is disposed above the position where each pneumatic device is placed in the flow path of the cooling air flow and below the cooling means (water-cooled cooler 50a). Has been. In the form example shown in FIG. 14, the exhaust port 15 is opened in the small box part 26 provided just under the cooler 50a.
The small box portion 26 is open so that the upper surface communicates with the cooler 50a, and an opening 26a is provided on the lower surface. Thereby, the cooling airflow flows. Further, the internal space in the small box portion 26 is a mixing space 27 that is mixed with the heated air exhausted from the exhaust port 15 when the cooling air flows from the bottom to the top. The heated air is at a high temperature and is mixed and diluted with the cooling air to disperse the heat and improve the cooling efficiency.

FIG. 15 is a view taken in the direction of arrow A in FIG. 13 and shows piping (a pressurized air supply piping and heated air exhaust piping) of the pump device 10b that supplies pressurized air to the air working device.
The hose 11b is a pipe that supplies pressurized air from the pump device 10b to an external air working device. The lower portion of the hose 11b is piped so as to pass horizontally below the position where each pneumatic device 10 is placed in the flow path of the cooling airflow. Since the pipes are arranged in this way, there is an aftercooler effect as described above.
Further, the exhaust pipe 13b is a pipe line that guides and exhausts high-temperature heated air to be discarded from the pump device 10b.

Then, at least a part of the exhaust pipe 13b is cooled by a cooling means (above the position where each pneumatic device 10 is placed in the flow path of the cooling air flow so as to be cooled by the cooling air flow. It is arranged below the water-cooled cooler 50a). In the embodiment shown in FIG. 15, the upper portion 13z of the exhaust pipe 13b is piped in the mixing space 27 of the small box portion 26 described above. The upper part 13z of the exhaust pipe 13b thus piped is forcibly cooled by the cooling air flow.
An adjustment valve 17 capable of adjusting the exhaust pressure of the heated air to be exhausted is provided at the tip of the upper portion 13z of the exhaust pipe 13b. In this embodiment, the operation portion 17a for changing the spring pressure when adjusting the exhaust pressure is exposed outside the small box portion 26, and the exhaust port 15b is located inside the small box portion 26. Has been placed.
As described above, since the upper portion 13z of the exhaust pipe 13b is cooled by the cooling airflow, the operating portion 17a of the regulating valve 17 can be prevented from becoming high temperature, and the operator can operate it appropriately.

FIG. 16 is a view taken in the direction of arrow A in FIG. 13 and shows piping (a suction piping for decompressed air and a piping for exhausting heated air) of the blower device 10c that generates a decompression that sucks air from the air working device.
By piping in this way, the pneumatic apparatus differs from the embodiment shown in FIG. 14 between the vacuum pump apparatus 10a and the blower apparatus 10c, but the same operational effects can be obtained.

FIG. 17 is a view taken in the direction of the arrow B in FIG. 13 and shows the piping (the pressurized air supply piping and the heated air exhaust piping) of the blower device 10 d that supplies the pressurized air to the pneumatic working device.
By piping in this way, although the pneumatic device differs from the embodiment shown in FIG. 15 between the pump device 10b and the blower device 10d, the same effect can be obtained. Note that the present embodiment is different from the embodiment of FIG. 15 in that there is no portion of the exhaust pipe that is cooled by the cooling air flow, and in that the safety valve 18 is provided instead of the regulating valve. .

Next, a coarse filter for capturing dust in the air so as to suppress the intrusion of dust into the box structure will be described with reference to the drawings.
FIG. 18 is a perspective view showing a state in which the coarse dust filter 90 can be folded, and FIG. 19 is a plan view in a state of being extended in a plane. FIG. 20 is a cross-sectional view showing an example of a connection form of the filter units 90A.

This coarse dust filter 90 suppresses the intrusion of dust into the box structure, and is provided in a flat plate shape that can be inserted between a pair of guide grooves 93 and 93 provided inside the box structure. At the same time, a plurality of filter units 90A constituted by a frame bar 94 whose outer edge is formed into a frame shape by a rod-shaped material so as to fit into the guide groove 93 and a filter medium 95 stretched on the frame bar 94 are planar. Are provided so that they can be folded in parallel.
Since the coarse filter 90 of this embodiment can be folded in the insertion direction, the maintenance space can be reduced.

Further, as shown in FIG. 20, reference numeral 96 denotes a connecting member, which is a pair of fitting portions 97 and 97 that are formed to be expandable by elasticity and are fitted on the frame rod 94, and the pair of fitting portions 97 and 97. And a connecting portion 98 having flexibility that can be folded back. Thus, the filter unit 90A is connected to each other to form the coarse dust filter 90. In the present embodiment, the three filter units 90A are connected to each other, but it is needless to say that two or four or more may be used depending on the place where the filter is mounted.
In addition, 95a is a sewing part of the filter medium 95,
Further, as shown in FIG. 19, reference numeral 99 denotes a handle, which is sewed on the filter medium 95 in the center of the front side of the frame bar 94 so that the coarse dust filter 90 can be easily pulled out. Yes.
In addition, 94a is a reinforcing rod (see FIG. 19), and 95a is a seam portion (see FIG. 20) of the filter medium.

The fitting portion 97 is provided with a C-shaped section 97 a that fits into the frame rod 94 having a circular section, and a tapered shape that is provided continuously on both sides from the C-shaped portion 97 a and guides when fitting into the frame rod 94. It is comprised by the part 97b. The fitting portion 97 is provided by an elastic material such as plastic. For this reason, as shown in FIG. 19, the frame rod 94 around which the end portion of the filter medium 95 is wound can be easily connected by being pushed into the fitting portion 97 so as to slide in the arrow direction. Note that a two-dot chain line in FIG. 19 indicates a state at a midway position where the filter unit 90 </ b> A is slid and fitted to the fitting portion 97.
Moreover, it is good for the connection part 98 to be provided with the material which has the softness | flexibility which can be turned back and has less air permeability than the part of a filter medium. For example, it is formed of a rubber material.

As shown in FIG. 1, the coarse dust filter 90 has a storage box below the position where each air device 10 is placed in the flow path of the cooling air flow and above the suction port 19 for taking in air. It is installed substantially horizontally so as to occupy 20 horizontal sections.
For this reason, the filter area can be widened, and the ventilation resistance can be kept small, so that the air volume of the cooling air can be suitably secured. In addition, the coarse dust filter 90 is plate-like and thin, and is horizontally arranged (horizontal). Therefore, the installation space in the storage box 20 is small, and the box structure can be made compact.
On the other hand, it is conceivable to arrange a vertically arranged (circularly placed) filter around the circumference of the portion corresponding to the height of the leg 92, but there is a dimensional limitation, and the filtration area is reduced. It is difficult to take large enough.

13 to 17, hoses 11 a and 11 b for connecting the pneumatic device 10 and an external device are piped so as to pass below the installation position of the coarse dust filter 90. Yes. That is, the hoses 11 a and 11 b are arranged under the coarse dust filter 90.
Cooling air flows through the coarse dust filter 90 after passing through the gaps between the hoses 11a and 11b, so that a suitable rectifying effect is produced and the ventilation resistance can be lowered. Thereby, it is possible to flow cooling air in a well-balanced manner with respect to the plurality of pneumatic devices 10, and to improve the cooling efficiency.

The suction port 19 of the present embodiment is provided on the lowermost surface of the storage box 20, and an air circulation portion is secured by the height of the legs 92 (see FIG. 1) being away from the floor surface. Nearly the entire bottom surface of the storage box 20 is wide and serves as a suction port 19 so that the ventilation resistance can be kept low.
Further, the coarse dust filter 90 is provided in a plate shape so as to be foldable, and is provided so as to be inserted in the horizontal direction in a state of being spread in a flat plate shape as shown in FIG. In this embodiment, as shown in FIG. 1, it is inserted from a slit-like insertion port 91 provided horizontally on the front surface of the storage box 20. For this reason, it can be replaced and stored without taking up space. In addition, the bending part (joint part 98) of the filter dust 90 can be provided with rubber | gum or a cloth material. Moreover, as the filter material, for example, a filter medium 95 in a form in which a plurality of meshes made of synthetic resin fibers are overlapped can be used. According to this filter medium 95, the peripheral portion can be formed in a stretched state by being hung around the frame bar 94 and sewn.

According to the coarse dust filter 90, the dust filter 90 is disposed upstream of the cooling airflow flowing from the lower side to the upper side of the storage box 20, and can take in dust that is sucked. Thereby, the pump and the blower built in the storage box 20 are suitably protected. Of course, the filters are also attached to the pump and the blower itself, respectively, because dust can be removed at the previous stage.
The air station as in the present embodiment is installed, for example, in a factory that handles paper such as printing and bookbinding for sucking and separating paper. In such a printing factory or the like, dust (such as corn flour) that dusts paper dust or sprays onto paper immediately after printing to prevent ink sticking becomes dusty. For this reason, pneumatic equipment such as a pump and a blower built in the air station can be suitably protected by suitably providing the coarse dust filter 90 as in this embodiment.

  In addition, a device for detecting clogging of the coarse dust filter 90 and an alarm device may be provided. For example, a bimetallic temperature detector is provided on a side frame corresponding to a portion immediately after the cooling air passes through the coarse dust filter 90, and an alarm device such as a patrol light that operates based on a signal generated by the detector is provided. It can be provided at a position where the operator can visually recognize it. According to this, if the coarse dust filter 90 is clogged and the temperature in the storage box 20 rises, an alarm is issued, which contributes to the safety of the apparatus.

Next, another embodiment (Example 1) of the pneumatic device station according to the present invention will be described with reference to FIG. The pneumatic device station includes a water-cooled cooler (water-cooled condenser) as in the above-described embodiment. Moreover, it differs from the embodiment described above in that the cooling airflow is a downward flow. Hereinafter, the difference will be mainly described.
Reference numeral 28 denotes a duct to which the exhaust pipe 13 of each air device 10 is connected. Therefore, high-temperature exhaust gas including exhaust gas from the safety valve intensively flows into the duct 28 (see the arrow shown in FIG. 21). In the internal space of the duct 28 (see FIGS. 21 and 22), the exhausted heated air is mixed with the cooling air flowing from the outside and diluted. For this reason, according to the internal space of this duct 28, the heat of exhaust_gas | exhaustion can be disperse | distributed similarly to the mixing space 27 shown to FIGS. The duct 28 is disposed outside the water-cooled condenser 50a (upstream of the water-cooled condenser 50a with respect to the flow of the cooling air flow). A blower (a pressure ventilation fan 40) is disposed at the bottom of the storage box 20.

Since it is configured in this manner, when air is sucked by the pressure ventilation fan 40, the heated air in the duct 28 is cooled by heat exchange through the water-cooled condenser 50a. Further, the water-cooled condenser 50a is arranged open to the outside so that heat can be exchanged by taking in outside air.
For this reason, the air after the exhaust gas is cooled by heat exchange by the water-cooled condenser 50a and the air after the outside air is cooled by the water-cooled condenser 50a are the cooling airflow (wind) of the downflow (downflow). And flows along the surface of the pneumatic device 10 (pump 10a or blower 10c). Thereby, the pump 10a and the blower 10c can be cooled suitably. At this time, since the pressurized ventilation fan 40 with an air supply specification is arranged at the lowermost part, there is an advantage that the rectified wind can easily flow and the cooling efficiency can be increased.
And the air after cooling the pump 10a and the blower 10c with the pressure ventilation fan 40 can be discharged | emitted out of the storage box 20 (refer the white arrow shown in FIG. 21).
Note that the pressure ventilation fan 40 can easily change the flow of the wind by changing the rotation direction of the impeller and the mounting direction of the blades, and can support both the exhaust specification and the supply specification. For this reason, changing the flow direction of the wind according to the operating conditions of the pneumatic device station can be easily performed.

Next, another embodiment (Example 2) of the pneumatic device station according to the present invention will be described with reference to FIG. This pneumatic station is different from the first embodiment in the arrangement of the pressure ventilation fan 40.
As is apparent from FIG. 22, in the present embodiment, the pressure ventilation fan 40 is installed inside the water-cooled condenser 50a. The pressure ventilation fan 40 generates a cooling air flow (down flow) that descends in the storage box 20 in order to cool the storage box 20 heated by the pneumatic device 10 (see the arrow shown in FIG. 22). ). Also by this, the pump 10a and the blower 10c can be suitably cooled similarly to the first embodiment, and the air having a required low temperature can be exhausted out of the storage box 20.

Next, another embodiment (Example 3) of the pneumatic device station according to the present invention will be described with reference to FIG. This pneumatic device station is different from the above-described embodiment in that it is an internal circulation type in which the cooling air flow is a circulation flow.
Reference numeral 55 denotes a circulation air flow path, which is a passage for circulating the cooling air flow in the storage box 20. In the present embodiment, a circulation air passage 55 is formed by providing a double structure by the storage box 20 and a cabinet (external storage box 56) in which the storage box 20 is built. That is, a space provided between the outer surface of the internal storage box 20 and the inner surface of the external storage box 56 is a circulation air flow path 55.
The circulation air passage 55 is not limited to this, and may be a passage provided outside the storage box 20 so as to communicate the upper end portion and the lower end portion of the internal storage box 20. Therefore, the circulation air flow path 55 may be constituted by a pipe (duct).

In this embodiment, a blower (a pressure ventilation fan 40) is disposed at the bottom of the storage box 20. According to this pressure ventilation fan 40, the air flow for cooling is generated so that air may be spouted from the lowest part.
As a result, a cooling air flow (upflow) that flows from the lower side to the upper side in the storage box 20 that stores a plurality of pneumatic devices 10 is generated, and the pneumatic device 10 can be effectively cooled as described above.
In addition, the air after passing through the storage box 20 is cooled by passing through the water-cooled condenser 50a together with the exhaust of the pneumatic device 10 discharged into the duct 28, and circulates down the circulation air flow path 55. (See arrow shown in FIG. 23). Since air flows from the inside to the outside of the water-cooled condenser 50a, the duct 28 is provided inside the water-cooled condenser 50a.
Thereby, the heated air in the storage box 20 can be efficiently and suitably cooled.
In addition, the installation place of the pressure ventilation fan 40 is not limited to a present Example, You may install in the other position in a basic circulation air path. However, care should be taken when installing the pressure ventilation fan 40 directly above the pneumatic device 10 in order to prevent problems caused by exposure to high-temperature air.

Next, another embodiment (Example 4) of the pneumatic device station according to the present invention will be described with reference to FIG. This pneumatic apparatus station is different from the third embodiment in that the circulating cooling airflow is a downward flow (downflow) in the storage box 20.
Also in this embodiment, the pressure ventilation fan 40 is disposed at the lowermost portion of the storage box 20. According to the pressure ventilation fan 40, the air in the storage box 20 is sucked and discharged to the circulation air flow path 55. Then, the air that has passed through the circulation air flow path 55 is cooled by passing through the water-cooled condenser 50 a together with the exhaust of the pneumatic device 10 discharged into the duct 28, and flows again into the storage box 20 for circulation. (See arrow shown in FIG. 24). Since air flows from the outside to the inside of the water-cooled condenser 50a, the duct 28 is provided outside the water-cooled condenser 50a.
Also by this, the heated pneumatic device 10 in the storage box 20 can be suitably cooled by the cooling air flow.

According to such a double structure of the storage box 20 and the external storage box 56, the operation sound generated from the pneumatic device 10 can be cut off twice, and the noise reduction performance can be improved. In addition, a closed cabinet structure can be realized, and the noise reduction performance can be improved by not leaking the operation sound of the pneumatic device 10.
Further, the pressure ventilation fan 40 is installed in a closed circuit and air is circulated, so that dust is not sucked from the storage box 20. For this reason, the air containing the dust which the pressure ventilation fan 40 inhaled does not discharge | release outside. Therefore, there is an advantage that the surrounding environment is not polluted.
Furthermore, since the exhaust is not discharged outside the pneumatic device station, a space for rectifying the exhaust is not required, and the installation space can be reduced. Further, even if the ambient (outside air) temperature or the like changes with respect to the circulating air, the influence is small and stable operation can be performed. On the contrary, since the influence on the surrounding environment can be reduced, there is an advantage that the energy consumption can be reduced as a whole.

By the way, when the airtightness inside the pneumatic device station becomes high, the internal pressure fluctuates depending on the operation of the pneumatic device 10 such as the pump 10a or the blower 10c. For this, an adjusting device such as a damper for keeping the pressure constant can be provided.
Furthermore, since the inside of the pneumatic device station is hermetically sealed, it is directly influenced by the operating condition of the pneumatic device 10 instead of being influenced by the external environment, and the internal environment is likely to fluctuate. For this, an appropriate control device for managing the temperature of the cold water and managing the amount of water can be provided so that the pneumatic device 10 and the circulating air inside the pneumatic device station are not overheated or cooled too much.
In addition, when dust is generated inside the pneumatic device station, a filter device for removing the dust may be provided.

The pneumatic device station of the embodiment and the embodiment described above can be suitably installed in a factory room that requires temperature management, such as a printing factory, for example.
In printing factories, many pneumatic devices such as vacuum pumps and blowers are used in order to operate devices for sucking and transporting printing paper. Further, for high-quality printing, it is necessary to maintain the room temperature at a constant, for example, 25 ° C.
According to the pneumatic device station of the present invention, a plurality of pneumatic devices can be suitably stored, and temperature management and the like can be suitably performed to maintain the indoor environment in a suitable state. It can solve suitably.

  As described above, the present invention has been described in various ways with preferred embodiments. However, the present invention is not limited to these embodiments, and many modifications can be made without departing from the spirit of the invention. That is.

It is a perspective view which shows the form example of the pneumatic apparatus station which concerns on this invention. It is a block diagram of the exhaust temperature adjustment system of a pneumatic apparatus station. It is explanatory drawing which shows the flow of the cooling step concerning the system of FIG. It is a graph which shows the relationship between the temperature change of cooling water, and the temperature change of exhaust gas. It is a graph which shows the relationship between the flow volume change of a cooling water, and the temperature change of exhaust_gas | exhaustion. It is a graph which shows the relationship between the load change of a pneumatic apparatus, and the temperature change of exhaust_gas | exhaustion. It is a perspective view which shows one form of the shelf-shaped support part of the storage box which concerns on this invention. It is a top view which shows the form example of the ladder of the shelf-shaped structure which concerns on this invention. It is a side view of the ladder of FIG. It is a front view of the ladder of FIG. It is a perspective view which shows one form of the rack structure of the storage box which concerns on this invention. It is a perspective view which shows one form of the shelf-shaped support part of the storage box which concerns on this invention. It is a front view which shows the example of 1 form of the pneumatic apparatus station which concerns on this invention. It is a side view which shows the example of 1 form of the pneumatic apparatus station which concerns on this invention. It is a side view which shows the example of 1 form of the pneumatic apparatus station which concerns on this invention. It is a side view which shows the example of 1 form of the pneumatic apparatus station which concerns on this invention. It is a side view which shows the example of 1 form of the pneumatic apparatus station which concerns on this invention. It is a perspective view which shows one example of the filter for pneumatic equipment stations. It is a top view which shows the state which the filter of FIG. 18 extended. It is sectional drawing which shows an example of the connection form of filter single bodies. 1 is a side view showing a first embodiment of a pneumatic device station according to the present invention. It is a side view which shows 2nd Example of the pneumatic apparatus station which concerns on this invention. It is a side view which shows 3rd Example of the pneumatic apparatus station which concerns on this invention. It is a side view which shows 4th Example of the pneumatic apparatus station which concerns on this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Air station 2 Unit cooler 3, 4, 5 Valve 6 Flow meter 7 Water temperature meter 10 Pneumatic device 11 Hose 12 Connection port 13 Exhaust piping 15 Exhaust port 20 Storage box 21 Box body 24 Sound absorbing material 25 Support column 30 Shelf-shaped support part 31 Opening part 40 Blower (pressure ventilator)
50 Cooling means 50a Cooler (water-cooled condenser)
55 Circulating air flow path 56 External storage box 60 Beam 61 Upper horizontal surface 61a Horizontal flat plate portion 62 Lower horizontal surface 62a Horizontal flat plate portion 63 Standing plate portion 65 Through hole 70 Ladder 71 Upper surface portion 72 Lower surface portion 73 Extension flat plate portion 74 Side plate part 75 Female thread part 77 End face part 80 Side beam 90 Coarse dust filter 90A Filter unit 93 Guide groove 94 Frame rod 95 Filter medium 96 Connecting member 97 Fitting part 98 Connecting part

Claims (5)

A pneumatic device that generates negative or positive air pressure, such as a vacuum pump or blower,
A storage box that can be soundproofed by housing the spatial pressure device into a plurality housing can Rutotomoni closed space,
An air blower for generating and exhausting a cooling air flow that flows from the lower side to the upper side in the storage box in order to cool the storage box heated by the pneumatic device by taking in outside air; and
A water-cooled cooler provided to cool by passing the cooling air flow;
A cooler unit for supplying cold water to the cooler;
At least one of water temperature control means for controlling the water temperature so as to adjust the temperature of the cold water supplied to the cooler and flow rate control means for controlling the flow rate so as to adjust the flow rate of the cold water supplied to the cooler is provided. et al is,
The storage box has at least one shelf-like support portion on which the pneumatic device is placed in the middle in the height direction, and the shelf-like support portion is opened to allow the flow of the cooling air flow. exhaust temperature conditioning system of the air pressure device station, characterized in that it comprises a part.   An exhaust port of an exhaust pipe for leading and exhausting heated air from the vacuum pump device which is the pneumatic device is opened above the position where each pneumatic device is placed in the flow path of the cooling air flow. 2. An exhaust temperature adjusting system for a pneumatic equipment station according to claim 1, further comprising a mixing space that is mixed with the heated air exhausted from the exhaust port when the cooling air flows from the bottom to the top. . The exhaust temperature adjustment of the pneumatic equipment station according to claim 1 or 2 , wherein the water temperature control means controls the water temperature of the cooler unit based on detection data by a water temperature detection device or the like for detecting the temperature of cooling water. system. The said flow control means controls flow volume by adjusting opening and closing of a control valve based on the detection data by the flow detection apparatus etc. which detect the flow volume of cooling water, The flow rate control means of Claim 1, 2, or 3 characterized by the above-mentioned. Pneumatic equipment station exhaust temperature control system. A general air conditioner installed to air-condition the factory room;
Plant room air conditioning system, characterized in that it comprises a factory indoor air conditioning exhaust temperature conditioning system of the air pressure system station according to claim 1, 2, 3 or 4, wherein also placed in a functional purpose as an auxiliary device.

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