JP2000274994A - Heat exchanger - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily expect a place becoming a cause of increasing a ventilating resistance by providing an exhaust tube extended from a coating booth to an inlet chamber of a heat exchanging chamber, and detecting an air volume of an exhaust fan, an air volume of the inlet chamber, and an air volume of an outlet chamber of the exchanging chamber. SOLUTION: An exhaust fan 56 is disposed on the way of an exhaust tube (exhaust duct) 57, and an exhaust air exhausted from a coating booth is supplied to an exhaust air inlet chamber 53a. The fan 56 is driven by a driver and rotated. As detectors, detectors 81, 82 and 83 for detecting an air volume of the fan 56, an air volume of the chamber 53a of a heat exchanging chamber and an air volume of an exhaust air outlet chamber 53b of the exchanging chamber to obtain the respective volumes are prepared. A control operation panel 90 has a converter for converting detected results such as a rotational speed, a driving power, a frequency, an air pressure, a wind speed or the like of the fan obtained from the detectors 81, 82 and 83 into the volumes, and measures a driving power of the driver of the fan 56.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] The present invention relates to a heat exchange device in a paint shop.

[0002]

2. Description of the Related Art Conventionally, as shown in FIG. 3, in a coating factory, the temperature and humidity of the outside air flowing into a coating booth 70 are set to predetermined values (for example, a temperature of 20 ° C. and a humidity of 70%).
An air-conditioning room 60 for adjusting the temperature is provided. Normal,
The temperature of the outside air changes between about 0 to 30 ° C. in one year, and when the difference between the outside air and the temperature of the air flowing into the coating booth (predetermined temperature) is large, the burden on the air conditioning room 60 is increased. Becomes larger. Therefore, the heat exchange chamber 50 is provided upstream of the air conditioning room 60, and the outside air before flowing into the air conditioning room 60 is brought close to a predetermined temperature in the heat exchange room 50, so that the load on the air conditioning room 60 can be reduced. Will be The heat exchanger 10 is arranged in the heat exchange chamber 50. The heat exchanger (total heat exchanger) 10 is substantially cylindrical, and has a plurality of axially extending passages 13 formed therein so as to allow air to pass in the axial direction, as shown in FIG. The heat exchanger 10 is rotatably supported around a central axis O, and rotates around the central axis O during heat exchange of air. Heat exchange room 5
0, a partition wall 51 is provided at the center in the vertical direction.
Outside air is supplied to the heat exchanger 10 located in the upper upper chamber 52 by the outside air fan 55. Also,
In order to effectively use the heat energy of the exhaust air discharged from the coating booth 70, the lower chamber 53 below the partition 51 is used.
The exhaust air exhausted from the coating booth 70 is supplied to the heat exchanger 10 located by the exhaust fan 56.
A part of the exhaust air that has flowed into the heat exchanger 10 located in the lower chamber 53 is diverted to the heat exchanger 10 before exiting to the side opposite to the inflow side.
Is moved to the upper chamber 52 by the rotation of the air, and exits from the heat exchanger 10 by the flow of the outside air, and is returned to the coating booth 7 again.
Flow towards zero. In addition, since paint mist may be contained in the exhaust air discharged from the coating booth 70, the paint adheres to the passage of the exhaust air. As a result, the ventilation resistance increases.

[0003]

However, since the heat exchange of the exhaust air is continued, the amount of paint adhered to the exhaust air passage increases, the ventilation resistance increases, and the energy for driving the exhaust fan 56 is wasted. Will be consumed. Since the paint does not always adhere uniformly to the exhaust air passage, the increase in the ventilation resistance does not always occur uniformly throughout the exhaust air passage. Therefore, it is desired that a place where the airflow resistance is increased is expected. When a place where the airflow resistance is increased is expected, the place is cleaned, the airflow resistance can be easily set to a normal state, and wasteful consumption of energy can be suppressed.
An object of the present invention is to provide a heat exchange device in a coating factory that can detect an abnormal place that causes an increase in ventilation resistance.

[0004]

The present invention that achieves the above object is as follows. (1) A heat exchanger provided with a passage through which air can pass is arranged, and a heat exchange chamber divided into an air inlet chamber and an air outlet chamber with the heat exchanger as a boundary; An exhaust pipe that extends to the inlet chamber of the chamber, and an exhaust fan that is disposed in the exhaust pipe and that supplies exhaust air exhausted from the coating booth to the heat exchange chamber, the exhaust fan including a driving unit;
A heat exchange device comprising: a detector configured to detect a flow rate of the exhaust fan, a flow rate of the inlet chamber of the heat exchange chamber, and a flow rate of the outlet chamber of the heat exchange chamber. (2) The heat exchange device according to (1), wherein the air volume of the exhaust fan is detected by measuring a rotation speed of the exhaust fan, a driving power of the exhaust fan, or a frequency of an inverter of a driving unit of the exhaust fan. . (3) The heat exchange device according to (1), wherein the air volume of the inlet chamber of the heat exchange chamber is detected by measuring an air pressure or a wind speed of the inlet chamber of the heat exchange chamber. (4) The heat exchange device according to (1), wherein the air volume of the outlet chamber of the heat exchange chamber is detected by measuring an air pressure or a wind speed of the outlet chamber of the heat exchange chamber.

The heat exchangers (1) to (4) are provided with detectors for detecting the air volume of the exhaust fan, the air volume of the inlet chamber of the heat exchange chamber, and the air volume of the outlet chamber of the heat exchange chamber. The air flow at each location of the fan, the inlet room of the heat exchange room, and the outlet room of the heat exchange room can be detected, and from places where the air volume changes from the initial air volume, due to abnormalities such as paint clogging, etc. You can predict where the airflow resistance is increasing,
The degree of abnormality such as paint clogging can be estimated by comparing with the initial air volume. In the heat exchanger of the above (2), the air volume of the exhaust fan is determined by measuring the number of revolutions of the exhaust fan, the driving power of the exhaust fan, or the frequency of the inverter of the drive unit of the exhaust fan, and converting the measured value to the air volume. Is detected. In the heat exchange device of the above (3), the air volume of the inlet chamber of the heat exchange chamber is detected by measuring the air pressure or the wind speed of the inlet chamber of the heat exchange chamber, and converting the measured value to the air volume. In the heat exchange device of the above (4), the air volume of the outlet chamber of the heat exchange chamber is detected by measuring the air pressure or the wind speed of the outlet chamber of the heat exchange chamber, and converting the measured value to the air volume.

[0006]

FIG. 1 shows a heat exchanging device for a coating booth air according to an embodiment of the present invention, and FIG. 2 shows air flow rates in an exhaust fan, an exhaust air inlet chamber, and an exhaust air outlet chamber. 3 shows a flow path of air in a coating plant, and FIG. 4 shows a heat exchanger of a heat exchanger. 3 and 4 are denoted by the same reference numerals because they show the same configuration as the conventional one.

As shown in FIG. 3, the air in the coating factory flows through the heat exchange room 50 (52), the air conditioning room 60, the coating booth 70, and the heat exchange room 50 (53) in this order. A duct is arranged between each. While the outside air flows into the heat exchange chamber 50, the exhaust air flows into the heat exchange chamber 50. In the air conditioning room 60, the temperature and humidity of the air supplied to the coating booth 70 are adjusted to predetermined values, for example, a temperature of 20 ° C. and a humidity of 70%.

First, a heat exchange apparatus according to an embodiment of the present invention is shown in FIG.
This will be described with reference to FIGS. In the embodiment of the present invention, the heat exchanging device is provided in a coating factory, and includes a heat exchanging chamber 50, an exhaust passage 57, an exhaust fan 56, and a plurality of detectors 81 and 8.
2 and 83.

The heat exchanger 10 is arranged in the heat exchange chamber 50. The heat exchanger 10 is a total heat exchanger. The outer shape is a cylindrical tube having a diameter of about 5 m and a length of 2 m.
As shown in FIG. 4, the inside is divided by a plurality of flat plates (aluminum plates) 11 arranged so as to pass through the central axis O of the cylindrical tube, for example, equally (in FIG. 2, 10 equally divided). , And further, each of the divided axially extending spaces is:
Multiple corrugated plates (aluminum plates) arranged in a substantially arc direction
12 are delimited. Thereby, the heat exchanger 1
0 forms a plurality of passages 13 extending in the axial direction through which air can pass. Further, the heat exchanger 10 reaches an arbitrary temperature by being heated. The heat exchanger 10 is rotatable around a central axis O by a rotating device.

The heat exchanger 10 is arranged at a central position in the heat exchange chamber 50 in the direction in which air flows. The heat exchange chamber 50 is partitioned by a partition wall 51 into an upper chamber 52 and a lower chamber 53. The partition 51 and the central axis O of each heat exchanger 10 are located in the same plane. In addition, a hole is formed in the partition wall 51 so as not to hinder the rotational driving of each heat exchanger 10. The heat exchange chamber 50 is mainly divided into four spaces by the heat exchanger 10 and the partition 51 as shown in FIG. The upper chamber 52 is divided into an upstream outside air inlet chamber 52a and a downstream outside air outlet chamber 52b with the heat exchanger 10 as a boundary, and the lower chamber 53 is an upstream exhaust air inlet chamber with the heat exchanger 10 as a boundary. 53a and a downstream exhaust air outlet chamber 53b. The exhaust air outlet chamber 53b is located below the outside air inlet chamber 52a, and the exhaust air inlet chamber 53a is located below the outside air outlet chamber 52b.

The heat exchanger 10 is provided with a washing device 30 for washing paint, dust and the like adhered to the surface of the heat exchanger 10. The cleaning device 30 includes a discharge nozzle 31 from which the cleaning liquid is discharged, pumps 32A and 32B for adjusting the discharge pressure of the cleaning liquid, and a collector 33 for collecting the cleaning liquid discharged from the discharge nozzle 31 and passing through the heat exchanger 10. And a driving device 34 for driving the discharge nozzle 31 and the collecting device 33.

The discharge nozzle 31 is provided to face the end face of the heat exchanger 10. The discharge nozzle 31 can be driven along the end face of the heat exchanger 10. The discharge nozzle 31
The cleaning efficiency is improved by being provided on both end surfaces (the end surface on the air inlet side and the end surface on the outlet side) of the heat exchanger 10. FIG. 1 shows an example in which discharge nozzles 31 are provided on both end surfaces of an exhaust air inlet side end surface 15a and an exhaust air outlet side end surface 15b of a heat exchanger.

The discharge nozzle 31 has a cleaning liquid supply hose 35.
Is communicated. Pumps 32A and 32B are provided on the upstream side of the cleaning liquid supply hose 35. The pump 32A can output a high pressure (for example, 300 kg / cm ² or more) discharge pressure. Pump 32B, the pump 32A lower any pressure (for example, any pressure in 0~300kg / cm ² or any pressure within the 0~200kg / cm ²⁾ can output a discharge pressure of .

The recovery unit 33 is disposed at a position facing the discharge nozzle 31 via the heat exchanger 10. In order to follow the drive of the discharge nozzle 31 via the heat exchanger 10, the nozzle can be driven along the end face of the heat exchanger 10.

The driving device 34 for driving the discharge nozzle 31 and the recovery unit 33 has a drive source 34a and a rail 34b for driving the discharge nozzle 31 and the recovery unit 33 in a direction along the end face of the heat exchanger 10. The rail 34b extends along the end surface of the heat exchanger 10 at a position separated from the end surface by a predetermined distance.
In FIG. 1, the rails 34b are provided on both end faces of the heat exchanger 10,
Each one is arranged. Each rail supports the discharge nozzle 31 and the recovery unit 33 so as to be drivable. The discharge nozzle 31 and the recovery unit 33 are individually driven along the rail 34b by the operation of the drive source 34a, or are driven integrally while the distance between them is maintained at a predetermined distance. Further, the rail may include the discharge nozzle 31 and the collection device 33, and the discharge nozzle 31 and the collection device 33 may be driven by being driven by the drive source 34a.

An exhaust passage (exhaust duct) 57 extends from the coating booth 70 to the exhaust air inlet chamber 53a of the heat exchange chamber 50.

The exhaust fan 56 is disposed in the exhaust duct 57 and supplies exhaust air exhausted from the coating booth 70 to the exhaust air inlet chamber 53a. The exhaust fan 56 includes a driving unit (not shown), and the fan rotates by driving the driving unit. The air volume of the exhaust fan 56 is determined by the rotation speed of the exhaust fan 56, and the air volume increases as the rotation speed of the exhaust fan 56 increases. The rotation speed of the exhaust fan 56 can be adjusted by adjusting the drive power or by adjusting the frequency of the inverter of the drive unit. Drive power or inverter frequency is controlled and
It is adjusted to an arbitrary value by the operation panel 90. The driving power or the frequency of the inverter is adjusted by the control / operation panel 90 so that the rotation speed of the exhaust fan 56 is maintained at a predetermined number. Therefore, for example, when the rotation speed of the exhaust fan 56 changes from a predetermined number while the exhaust fan 56 is being driven, the driving power or the frequency of the inverter is automatically adjusted by the control / operation panel 90,
Immediately, the rotation speed of the exhaust fan 56 is returned to the predetermined number.

The detector can detect the air volume of the exhaust fan 56, the air volume of the exhaust air inlet chamber of the heat exchange chamber, and the air volume of the exhaust air outlet chamber of the heat exchange chamber. Are provided, respectively.

As a detector for detecting the air volume of the exhaust fan 56, a rotation speed detection sensor can be used. The rotation speed detection sensor is arranged on the rotation axis of the exhaust fan 56.
Since there is a correlation between the rotation speed of the exhaust fan and the airflow, the airflow can be obtained from the rotation speed. The rotation speed detected by the rotation speed detection sensor is transmitted to the control / operation panel 90, and is converted into an air volume in the control / operation panel 90. In addition, as the detector 81 that detects the air volume of the exhaust fan 56, a control / operation panel 90 that controls the driving power of the driving unit of the exhaust fan 56 can be used. control·
The change in the driving power of the drive unit indicated by the operation panel 90 is converted into an air volume in the control / operation panel 90. Further, as a detector 81 for detecting the air volume of the exhaust fan 56, the exhaust fan 5
A control / operation panel 90 for controlling the frequency of the inverter of the drive unit 6 can also be used. A change in the frequency of the inverter indicated by the control / operation panel 90 is converted into an air volume in the control / operation panel 90.

As the detector 82 for detecting the air volume of the exhaust air inlet chamber 53a of the heat exchange chamber 50, a pressure sensor for measuring the air pressure of the exhaust air inlet chamber 53a of the heat exchange chamber 50 can be used. The pressure sensor 82 is disposed in the exhaust air inlet chamber of the heat exchange chamber. FIG. 1 shows an example in which the pressure sensor 82 is attached to the recovery unit 33 and is disposed in the exhaust air inlet chamber 53a. The detected air pressure is transmitted to the control / operation panel 90, and is converted into an air volume in the control / operation panel 90. Further, as a detector for detecting the air volume of the exhaust air inlet chamber 53a of the heat exchange chamber 50, a wind speed sensor (not shown) for measuring the wind speed of the air in the exhaust air inlet chamber may be used. The wind speed sensor is disposed in the exhaust air inlet chamber of the heat exchange chamber 50. Controlling the detected wind speed
It is transmitted to the operation panel 90 and is converted into an air volume in the control / operation panel 90.

As the detector 83 for detecting the air volume of the exhaust air outlet chamber 53b of the heat exchange chamber 50, a pressure sensor for measuring the air pressure of the exhaust air outlet chamber 53b of the heat exchange chamber 50 can be used. The pressure sensor 83 is disposed in the exhaust air outlet chamber 53b of the heat exchange chamber 50. FIG. 1 shows an example in which the pressure sensor 83 is attached to the collector 33 and is disposed in the exhaust air outlet chamber 53b. The detected air pressure is transmitted to the control / operation panel 90, and is transmitted to the control / operation panel 9
At 0, it is converted to an air volume. In addition, a wind speed sensor (not shown) that measures the wind speed of the air in the exhaust air outlet chamber may be used as a detector that detects the amount of air in the exhaust air outlet chamber of the heat exchange chamber. The wind speed sensor is disposed in the exhaust air outlet chamber 53b of the heat exchange chamber 50. The detected wind speed is transmitted to the control / operation panel 90, and is converted into an air volume in the control / operation panel 90.

The control / operation panel 90 includes the detectors 81 and 8
A conversion unit is provided for converting the detection results, such as the number of revolutions of the exhaust fan, the driving power, the frequency, the air pressure, the wind speed, etc., obtained from 2, 83 into an air volume. Further, the control / operation panel measures the driving power of the drive unit of the exhaust fan 56, or
And a detecting unit 81 for measuring the frequency of the inverter of the driving unit.

Next, the operation of the above device will be described. First, outside air is introduced into the outside air inlet chamber 52a by the fan 55 arranged on the upstream side of the introduction path 54. The outside air passes through the passage 13 of the heat exchanger 10 to the outside air outlet chamber 52b. At this time, since the heat exchanger 10 is driven to rotate at a predetermined speed (for example, 15 rpm / min), a part of the outside air in the passage 13 is supplied to the lower chamber 53.
Go to The outside air that has moved to the lower chamber 53 exits to the exhaust air outlet chamber 53b and is discharged from the heat exchange chamber 50.
Further, since the heat exchanger 10 is heated to an arbitrary temperature, the outside air exchanges heat while passing through the passage 13 of the heat exchanger 10 and approaches the arbitrary temperature.

Then, air is supplied from the outside air outlet chamber 52b to the air-conditioning chamber 60. The air is supplied to the air-conditioning room 60 at a predetermined temperature and humidity, for example, a temperature of 20 ° C. and a humidity of 7.
After being adjusted to 0%, it is introduced into the coating booth 70 at a predetermined flow rate. The air is caused to flow downward in the coating booth 70 by the fan 61 at a predetermined flow rate, and is discharged from below. The air adsorbs the paint mist in the painting booth 70. Then, a part of the air is exhausted from the coating booth 70 with the paint adsorbed.

The exhaust air flows through the exhaust duct 57 from the coating booth 70 side to the heat exchange chamber 50 by the exhaust fan 56, and is introduced into the exhaust air inlet chamber 53 a of the lower chamber 53 of the heat exchange chamber 50. And the exhaust air is heat exchanger 1
Flows into zero. Since the heat exchanger 10 continues to rotate, a part of the exhaust air is moved to the upper chamber 52 of the heat exchange chamber 50 before exiting to the exhaust air outlet chamber 53b of the heat exchanger 10. In the upper chamber 52, an air flow is formed from the outside air inlet chamber 53 a to the outside air outlet chamber 53 b, and the exhaust air in the heat exchanger 10 moved from the lower chamber 53 to the upper chamber 52 is discharged from the upper chamber 52. (Air outside air) flows through the outside air outlet chamber 52b. Further, the remaining portion of the exhaust air in the lower chamber passes through the heat exchanger 10, passes through the exhaust air outlet chamber 53 b, and is discharged from the heat exchange chamber 50.
Exhaust air passes through the heat exchanger 10 and a part of the air exits to the outside air outlet chamber 52b again, so that the heat energy of the exhaust air is effectively used.

During the heat exchange of air by the heat exchanger 10, the air volume of the exhaust fan 56, the air volume of the exhaust air inlet chamber 53a, and the air volume of the exhaust air outlet chamber 53b are continuously detected. Then, as a result of the detection, if the air volume at each location has changed from the initial value, it is possible to predict a location where there is an abnormality such as paint clogging from the location where the air volume has changed, and compare the location with the initial air volume. By comparison, the degree of abnormality such as paint clogging can be predicted.

The following shows some examples of various patterns when there is an abnormality such as paint clogging in the heat exchange device. As shown in FIG. 2, the initial air volume of the exhaust fan 56 is A, the initial air volume of the exhaust air inlet chamber (value converted from the air pressure P1) is B, and the initial air volume of the exhaust air outlet chamber (air pressure P2).
Is C. In this case, A,
B and C are reference values. Exhaust fan 5 after elapse of arbitrary time
6 is equal to the reference value A, the air volume in the exhaust air inlet chamber 53a is equal to the reference value B, and the air volume in the exhaust air outlet chamber 53b is smaller than the reference value C, the heat exchanger 1
It is expected that 0 has an abnormality. After the elapse of an arbitrary time, the air volume of the exhaust fan 56 is equal to the reference value A, the air volume of the exhaust air inlet chamber 53a is smaller than the reference value B, and the air volume of the exhaust air outlet chamber 53b decreases from the reference value B to the reference value C. If the width is the same as the width and the amount is smaller than the air volume of the exhaust air inlet chamber 53a, at least one of the inside of the exhaust duct 57 downstream of the exhaust fan 56 and the exhaust air inlet chamber 53a causes an abnormality such as paint clogging. It is expected that there will be. After the elapse of an arbitrary time, the air volume of the exhaust fan 56 becomes equal to the reference value A.
And the air flow rate of the exhaust air inlet chamber 53a is lower
6, the air flow rate in the exhaust air outlet chamber 53b is equal to the width of the decrease from the reference value B to the reference value C and is smaller than the air flow rate in the exhaust air inlet chamber 53a. It is expected that there is an abnormality in at least one of the exhaust duct 56 and the exhaust duct 57 upstream of the exhaust fan 56. After the elapse of an arbitrary time, the air volume of the exhaust fan 56 is equal to the reference value A, the air volume of the exhaust air inlet chamber 53a is smaller than the reference value B, and the air volume of the exhaust air outlet chamber 53b decreases from the reference value B to the reference value C. If the width is larger than the width and is smaller than the air volume of the exhaust air inlet chamber 53a,
It is expected that at least one of the inside of the exhaust duct 57 downstream of the exhaust fan 56 and the exhaust air inlet chamber 53a and the heat exchanger 10 are abnormal.

Since a portion where an abnormality has occurred can be predicted, the portion can be efficiently cleaned mainly.
The paint clogging occurring in the heat exchanger 10 is caused by the cleaning device 30.
Washed by. The discharge pressure of the cleaning liquid is adjusted according to the degree of clogging of the paint. When the paint is frequently clogged, an operation instruction is issued to the high-pressure pump 32a, and a high pressure (for example, 300 kg / cm ^{2) is} output from the discharge nozzle 31.
The cleaning liquid is discharged at (water pressure). When there is little clogging of the paint, an operation instruction is issued to the high-pressure pump 32b, and an arbitrary pressure (for example, 0
The cleaning liquid is discharged at a water pressure selected between ３００300 kg / cm ² . At a position facing the discharge nozzle 31 via the heat exchanger 10, the collecting device 33 whose position is adjusted by the driving device 34 is disposed.
The cleaning liquid discharged into the heat exchanger 10 from the heat exchanger 1
After passing through the heat exchanger 10 together with the paint and the like attached to 0,
It is collected in the collecting device 33.

[0029]

According to the heat exchanger of the present invention, a detector is provided for detecting the air volume of the exhaust fan, the air volume of the heat exchange chamber, and the air volume of the outlet chamber of the heat exchange chamber. The air flow at each location of the fan, the inlet room of the heat exchange room, and the outlet room of the heat exchange room can be detected, and from places where the air volume changes from the initial air volume, due to abnormalities such as paint clogging, etc. You can predict where the airflow resistance is increasing,
The degree of abnormality such as paint clogging can be estimated by comparing with the initial air volume. According to the heat exchanger of the second aspect, the air volume of the exhaust fan is obtained by measuring the rotation speed of the exhaust fan, the driving power of the exhaust fan, or the frequency of the inverter of the driving unit of the exhaust fan, and converting the measured value to the air volume. Is detected by According to the heat exchange device of the third aspect, the air volume of the inlet chamber of the heat exchange chamber is detected by measuring the air pressure or the wind speed of the inlet chamber of the heat exchange chamber, and converting the measured value to the air volume. According to the heat exchange device of the fourth aspect, the air volume of the outlet chamber of the heat exchange chamber is detected by measuring the air pressure or the wind speed of the outlet chamber of the heat exchange chamber, and converting the measured value to the air volume.

[Brief description of the drawings]

FIG. 1 is a schematic view of a heat exchange device according to an embodiment of the present invention.

FIG. 2 is a diagram showing a flow rate of an exhaust fan, a flow rate of an exhaust air inlet chamber, and a flow rate of an exhaust air outlet chamber of the heat exchange device according to the embodiment of the present invention.

FIG. 3 is a schematic view showing an air flow common to the embodiment of the present invention and the related art.

FIG. 4 is a side view of a heat exchanger of a heat exchange device common to the embodiment of the present invention and the related art.

[Explanation of symbols]

 Reference Signs List 10 heat exchanger 13 passage 50 heat exchange chamber 53a exhaust air inlet chamber (inlet chamber) 53b exhaust air outlet chamber (outlet chamber) 56 exhaust fan 57 exhaust passage 70 painting booth 81, 82, 83 detector

Claims (4)

[Claims] A heat exchanger provided with a passage through which air can pass; a heat exchange chamber divided into an air inlet chamber and an air outlet chamber with the heat exchanger as a boundary; An exhaust passage extending to the inlet chamber of the heat exchange chamber; and an exhaust fan provided in the exhaust passage and having a drive unit for supplying exhaust air exhausted from the coating booth to the heat exchange chamber. A heat exchange device comprising: a detector configured to detect a flow rate of an exhaust fan, a flow rate of the inlet chamber of the heat exchange chamber, and a flow rate of the outlet chamber of the heat exchange chamber. 2. The heat according to claim 1, wherein the air volume of the exhaust fan is detected by measuring a rotation speed of the exhaust fan, a drive power of the exhaust fan, or a frequency of an inverter of a drive unit of the exhaust fan. Exchange equipment. 3. The heat exchange device according to claim 1, wherein the air volume of the inlet chamber of the heat exchange chamber is detected by measuring an air pressure or a wind speed of the inlet chamber of the heat exchange chamber. 4. The heat exchange device according to claim 1, wherein the air volume of the outlet chamber of the heat exchange chamber is detected by measuring an air pressure or a wind speed of the outlet chamber of the heat exchange chamber.