JPS63190671A - Painting booth - Google Patents

Abstract

PURPOSE:To suppress the lowering in waste heat recovery efficiency caused by the adhesion and accumulation of paint mist, by performing the heat exchange of the washing solution having achieved its washing action in a paint mist removing apparatus with a heat recovering heating medium in the transfer groove of the washing solution. CONSTITUTION:The washing water W having achieved its washing action in a paint mist removing apparatus flows in a transfer groove 11 from a receiving water tank 10 to be returned to a storage tank 12 and is purified by a paint dregs separator 13 and a separated paint dregs scraper 14 to be again supplied to a washing water flow down tank 6 by a recirculation pump 15. The heat exchanger 27 of the heat pump 26 connected to a temp. control coil 17 is arranged to the transfer groove 11 and the heat exchange of the heat recovery heating medium of the heat pump 26 with the washing water W after washing action is performed to suppress the waste heat loss of a painting booth. A paint viscosity lowering agent such as caustic soda is mixed with the washing water W to prevent the adhesion of paint particles to machinery.

Description

[Detailed Description of the Invention] [Field of Industrial Application] The present invention relates to a painting booth for painting automobile bodies, casings of home appliances, etc. The present invention relates to a painting booth equipped with an air conditioner and a paint mist removal device that captures and removes paint mist in the exhaust gas by bringing the exhaust gas from the painting work area into contact with a cleaning liquid.

[Conventional technology]

Conventionally, in order to suppress energy loss by recovering the waste heat carried out of the system together with the exhaust gas from the painting work area in the above-mentioned painting booth, the cleaning solution was circulated in the paint mist removal device, and then As shown in Fig. 3, there is a total heat exchanger (total heat exchanger) that preheats the outside air for several people by exchanging heat between the exhaust gas that has passed through the paint mist removal device (8) and the outside air for several people to the air conditioner (3). 28), or, as shown in Figure 4, a heat pump (26) is installed that uses the exhaust gas that has passed through the paint mist removal device (8) as a heat receiving source, and the heat pump (26) performs air conditioning. Vessel (3)
The heating medium liquid for the temperature control coil (17) was heated.

In other words, the most direct way to recover waste heat from the painting work area is to recover the amount of heat retained in the exhaust gas before it passes through the paint mist removal device, but in the paint mist removal device, the cleaning fluid is circulated using a circulation pump. If used, under steady-state operating conditions, the circulating cleaning fluid will reach an equilibrium state due to contact with the exhaust gas, with a temperature as close as possible to the ventilation gas dew point temperature in the painting work area, thus preventing the painting work from occurring. Even after passing through the paint mist removal device, most of the exhaust heat from the area remains retained in the exhaust gas as the amount of heat retained in the exhaust gas.

In other words, sufficient heat can be recovered even from the exhaust gas that has passed through the paint mist removal device, and paint mist has also been removed from the exhaust gas that has passed through the paint mist removal device, making it possible to recover sufficient heat from the exhaust gas that has passed through the paint mist removal device. From the viewpoint of suppressing the adhesion and accumulation of paint mist, as mentioned above, the exhaust gas after passing through the paint mist removal device and the heat medium for exhaust heat recovery (heat medium liquid for some outside air or temperature control coils, etc.) The exhaust heat was recovered by exchanging heat (I am unable to provide references).

[Problem that the invention seeks to solve]

However, even though the paint mist is removed by contact with the cleaning liquid, a considerable amount of fine paint mist still remains in the exhaust gas after passing through the paint mist removal device. However, due to the high stickiness of the paint mist remaining in the exhaust gas, the heat exchanger for exhaust heat recovery (total heat exchanger for outside air)
37) and the heat receiving side heat exchanger (25) of the heat pump (24)
), etc.), and as a result, the heat exchange efficiency (that is, the exhaust heat recovery efficiency) decreases significantly, making it impossible to achieve sufficient exhaust heat recovery.

The purpose of the present invention is to move away from the conventional concept of recovering exhaust heat directly from exhaust gas, and to eliminate the adhesion of paint mist through rational exhaust heat recovery that focuses on removing paint mist through contact between exhaust gas and cleaning fluid. The purpose of this invention is to suppress a decrease in exhaust heat recovery efficiency due to deposition, and also to downsize the exhaust heat recovery configuration.

[Means for solving problems]

The characteristic configuration of the painting booth according to the present invention is that it is equipped with a paint mist removal device that removes paint mist from the exhaust gas by bringing the exhaust gas from the painting work area supplied with temperature-controlled ventilation gas into contact with the cleaning liquid. A heat exchange device that recovers waste heat from the painting work area by exchanging heat between the cleaning fluid that has been cleaned by the paint mist removal device and a heat recovery heat medium is installed in the transfer groove for the cleaning fluid that has been cleaned by the paint mist removal device. The functions and effects are as follows.

[For production]

In other words, the contact between the exhaust gas and the cleaning liquid for paint mist removal is used for direct heat exchange in which the exhaust gas transfers waste heat to the cleaning liquid, and the exhaust heat transferred to the cleaning liquid through the direct heat exchange is recovered with the cleaning liquid. It is recovered from the cleaning liquid through heat exchange with the heating medium.

At that time, the cleaning liquid after the cleaning action contains paint slag captured from the exhaust gas, but paint particles are generally less sticky in liquid than in gas; Although it is impossible to mix paint tack reducing agents into the liquid, it is easy to mix various paint tack reducing agents into the liquid. Because it is faster and it is easier to avoid adhesion of paint particles, it is better to exchange heat between the cleaning liquid and the heat recovery medium than the conventional method of exchanging heat between the exhaust gas and the heat recovery medium. Moreover, by performing this heat exchange in the transfer groove, adhesion and accumulation of paint particles on the heat exchange device for exhaust heat recovery can be suppressed.

When a heat medium liquid is used as a heat medium for heat recovery, the conventional model uses a liquid-to-gas heat exchange, but the present invention uses a liquid-to-liquid heat exchange. Since the washing water flows at a relatively high speed and the heat recovery efficiency is high, the heat exchange efficiency itself can be improved compared to the conventional type.

The above-mentioned effects occur in both types of paint mist removal equipment, such as those that temporarily consume the cleaning liquid and those that use it recirculatingly. By recovering exhaust heat from the cleaning liquid, the exchange of exhaust heat through direct heat exchange between the circulating cleaning liquid and the exhaust gas continues.

〔Effect of the invention〕

Since waste heat from the painting area can be recovered with high efficiency over a long period of time, it has become possible to further reduce energy loss compared to conventional equipment, which in turn has led to reductions in running costs.

The high heat exchange efficiency makes it possible to downsize the heat exchange configuration, making it possible to utilize waste heat in an advantageous manner in terms of space.

〔Example〕

Next, the present invention will be explained in detail.

Figure 1 shows the overall configuration of the painting booth, and shows the painting robot (
An air conditioner (
Air outlet (4) that blows out the temperature-controlled ventilation air from (3) downward.
), and the floor is formed with a lattice-structured exhaust port (5), and as ventilation air is supplied from the outlet (4), excess spray paint mist in the work area (2) is removed together with the air within the area. It is designed to be discharged from (5).

In the figure (^) is the object to be coated.

A cleaning water flow tank (6) is provided below the floor with a grid structure to catch fallen paint lumps and exhaust air from the work area (2), and also to prevent overflow from the cleaning water flow tank (6). A curved constriction flow path (7
), thereby forming a paint mist removal device (8) that captures and removes paint mist in the exhaust air by bringing the exhaust air into contact with cleaning water (circle).

The exhaust air that has passed through the paint mist removal device (8) is discharged to the outside of the system via an exhaust fan (9).

The cleaning water (W) after the cleaning action in the paint mist removal device (8) is transferred from the water tank (10) to the transfer groove (11).
), the paint slag separator (
13) and the separated paint slag scraper (14), the cleaning water is sent to the lower tank (6) again by the circulation pump (15).
).

On the other hand, the air conditioner (3) includes a pre-filter (16), a temperature control coil (17), a humidifier (18), and an eliminator (19).
, a cooling coil (20), and a heating coil (21) are installed inside, and the outside air taken in from the outside air intake port (22) is subjected to dust removal processing, temperature control processing, and humidity adjustment processing before being supplied as ventilation air. Air is supplied to the outlet (4) by a fan (23).

In the figure, (24) is a cold heat source device that circulates and supplies low-temperature refrigerant such as cold water or brine to the cooling coil (20), and (25) is a cold source device that supplies hot water, steam, etc. to the heating coil (21). This is a heat source device that circulates and supplies high-temperature heat medium.

A heat pump (26) connected to the temperature control coil (17)
) as shown in Fig. 2 of the pipe heat exchanger (27),
The heat exchanger (27) is arranged in the transfer groove (11) so that the heat medium for heat recovery of the heat pump (26) and the cleaning water after the cleaning action exchange heat in the transfer groove (11). As a heat exchanger on the heat receiving side, the heat exchanger (27) recovers thermal heat from the washing water (W) after the washing action, and circulates and supplies the hot water to the temperature control Koinoden 17) to heat the outside air for several people, and the heat exchanger (27) The heat pump (26) is used as a heat exchanger on the heat radiation side to recover cold heat from the washing water (W) after the washing action, and circulates and supplies cold water to the temperature control coil (17) to cool the outside air for several people.
It is configured so that it can be switched. In other words, due to the contact between the exhaust air and the cleaning water in the paint mist removal device (8), the heat given to and discharged from the cleaning water can be used as a heat source for heating or as a cold source for heat radiation. By using this system to control the temperature of ventilation gas, waste heat loss in the paint booth is suppressed and the energy required for air conditioning is reduced.

In addition, the washing water (W) includes a downstream tank (6) and a storage tank (12).
In order to suppress the adhesion and accumulation of paint slag on the tank walls and the adhesion and accumulation of paint slag on the paint slag separator (13), a paint tack reducing agent such as caustic soda is mixed. Mixing a paint tack reducing agent is also effective in preventing adhesion and accumulation on the vessel (27) and maintaining high exhaust heat recovery efficiency.

[Another example]

The heat exchange with the wash water (W) may be configured to be used for purposes other than air conditioning, and the specific type of the heat exchanger may be other than the pipe type. Therefore, the heat exchanger (27) is referred to as a heat exchange device (27).

Various liquids can be used in place of the washing water (A), and these are collectively referred to as the washing liquid (W).

Also, mixing a paint tack reducing agent into the cleaning liquid (W)
Although it is extremely effective in maintaining high exhaust heat recovery efficiency, it may be omitted.

The temperature-controlled ventilation gas supplied from the air conditioner (3) to the painting work area (2) is not limited to air.

[Brief explanation of the drawing]

The drawings show an embodiment of a coating booth according to the present invention, with FIG. 1 being a block diagram of the entire coating booth, and FIG. 2 being a schematic diagram of a heat exchanger. FIGS. 3 and 4 are conventional configuration diagrams. (2)...Painting work area, (3)...Air conditioner, (8)...Paint mist removal device, (11
)...Transfer groove (27)...Heat exchanger,
(匈)・・・・・・Cleaning liquid.

Claims (1)

[Claims] Air conditioner (
3), and a painting booth equipped with a paint mist removal device (8) that captures and removes paint mist in the exhaust gas by bringing the exhaust gas from the painting work area (2) into contact with the cleaning liquid (W). and a heat exchange device for recovering exhaust heat from the painting work area (2) by exchanging heat between the cleaning liquid (W) after the cleaning action in the paint mist removal device (8) and a heat recovery heat medium. (27) is arranged in the transfer groove (11) for the cleaning liquid (W) after cleaning.