KR100294069B1 - Welding fume toxicity test device - Google Patents

Abstract

The present invention relates to a welding fume toxicity test apparatus, and in the related art, the necessity to study the influence of welding fume (FUME) generated during welding work is increased as the occupational disease caused by the welding work increases. There was a problem that the welding fume toxicity study to be tested by injecting into the airway of the experimental animal after collecting the welding fume because the experimental device was not developed.

Accordingly, the present invention provides a welding fume generator for automatically generating a welding fume by approaching a welding rod to a rotating metal plate, an inlet chamber which connects the welding fume generator with a duct and observes the effect on the experimental animal after the generated welding fume is introduced. It is a useful invention that consists of a fume collector which drives the turbo fan to suck the welding fume and collects the residual welding fume and filters the welding fume automatically and safely.

Description

Welding fume toxicity test device

The present invention relates to a toxic experiment apparatus for automatically generating a welding fume to test the effect on the animal, and more particularly, a welding fume generator for automatically generating a welding fume by approaching a welding rod to a rotating metal plate, connected to the welding fume generator and the duct And a fume collector for observing the effect on the test animal after the generated welding fume is introduced, and a fume collector for driving the turbo fan to suck the welding fume and collecting and filtering the remaining welding fume. The present invention relates to a welding fume toxicity test apparatus for allowing animal testing.

In general, during welding in the industrial field, the welding rod melts and the welding fume is generated from the welding rod and the base metal, and the welding fume is a small particle formed by the condensation of the evaporated material by heat, and the average diameter is 0.1 micron. It is composed of heavy metals such as nickel, manganese and the like.

The following shows the main components of the welding fume generated during the welding of stainless steel. All the results were expressed as the average and standard deviation. The results were measured 20 times at 20000 times with electron microscope.

Welding fume containing the above components may be inhaled into the human body through the respiratory tract, causing lung cancer, pneumoconiosis, manganese poisoning, etc. may affect the respiratory system and nervous system. In recent years, six non-separated perforations occurred to six workers who worked for welding for 10 to 20 years.In 1999, 11 welding workers in Pohang were diagnosed with manganese poisoning due to Parkinson's syndrome. Was acknowledged as a occupational disease.

Therefore, it is necessary to study the disease caused by the welding workers exposed to the welding fume. As a part of this, the necessity of a device to artificially generate the welding fume and expose it to the experimental animal has increased.

However, until now, a separate experimental device for generating and testing a welding fume has not been developed, and thus, a situation in which the welding fume is collected has a considerable difficulty. In other words, in order to collect the welding fume, as in the existing industrial field, the human body collects the welding fume generated by bringing the welding rod closer to the metal plate, which affects the respirator of the experimenter who attempts the welding. There is a problem such as being.

In particular, the artificially collected welding fume has a very small collection amount, and thus it is difficult to continuously study the toxicity of the welding fume since it takes a long time to collect the required amount of welding fume for one animal experiment. Due to the weakness of the welding fume research has been a problem.

Therefore, an object of the present invention is to solve the above problems, by generating a welding fume to collect it and to enable the welding fume animal inhalation toxicity test to expose the test animal to the welding fume, the welding fume exhibits any reaction to the animal The purpose of the present invention is to provide a welding fume toxicity test apparatus that can determine whether the health effects indirectly affect the human health, that is, hazard assessment.

The purpose of the present invention as described above is a welding fume generator for automatically generating a welding fume by approaching a welding rod to the metal rotating plate, and the inlet to connect the welding fume generator and the duct and observe the effect on the experimental animal after the generated welding fume is introduced This is achieved by consisting of a chamber and a fume collector which drives the fan to suck the weld fumes and collects and filters the remaining weld fumes.

The present invention is to automatically generate a welding fume in a sealed welding fume generator and to collect and collect the experimental fume into the inlet chamber into which the experimental animal is placed, to test the effects on the experimental animal, and so that the remaining welding fume is filtered and discharged from the weld fume collector. Since the toxicity of the welding fume can be tested safely and conveniently, the above object can be achieved.

1 is a block diagram showing an embodiment of a welding fume toxicity test apparatus according to the present invention.

2 is a block diagram showing an embodiment of a welding fume generator according to the present invention.

<Description of the symbols for the main parts of the drawings>

1: welding fume generator 5: welding rod

6: metal rotating plate 7: canopy hood

14, 17, 31: motor 18, 37: controller

19: duct 20: inlet chamber

21 ': inlet flange 22': outlet

23: door 24: laboratory

30: fume collector 32: fan

36 filter 38 suction port

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic view showing an embodiment of a welding fume toxicity test apparatus according to the present invention, Figure 2 is a perspective view showing a fume generator of the welding fume toxicity test apparatus according to the present invention as shown in the drawings The welding fume toxicity test apparatus includes a welding fume generator 1, an inlet chamber 20 through which the welding fume generated by being connected to the welding fume generator 1 and the duct 19 flows, and a fume collector 30 for collecting and filtering the remaining welding fume. It is composed of.

Welding fume toxicity test apparatus according to the present invention as described above is a welding rod 5 for generating a welding fume by approaching the metal rotating plate 6 and the metal rotating plate 6 rotates at a predetermined speed, the upper portion of the metal rotating plate 6 It includes a canopy hood (7) installed to collect the welding fume, the welding fume generator (1) consisting of a controller 18 for controlling the rotational speed of the metal rotating plate (6) and adjusting the position of the welding rod (5).

In addition, the inlet chamber 20 according to the present invention has a welding fume inlet flange 21 ′ formed at one side of the upper plate 21, an outlet 22 ″ formed at one side of the lower plate 22, and a waste storage 22 at the lower side thereof. ') Is installed, the door 23 for the entrance and exit of the experimental animal is installed on one side, the other end of the duct 19 connected to the canopy hood 7 of the welding fume generator 1 is made by combining.

In addition, the fume collector 30 is connected to the outlet 22 ″ of the inlet chamber 20 and the hose 25 to filter the inlet port 38 through which the residual welding fume is introduced, and the air introduced from the inlet port 38. It consists of a filter 36 and a fan 32 that rotates with a motor for intake of air through the inlet.

That is, the welding fume generator 1 according to the present invention includes a metal rotating plate 6 installed in the sealed container 3 as shown in FIG. 2 and rotating according to the driving of the motor 14; A welding rod 5 approaching the rotating metal rotating plate 6 to generate a welding fume; A welding rod holder 4 installed on the support 8 after the welding rod 5 is coupled; Welding rod holder slide (10) consisting of a moving screw (9) for moving the screwed support 8 by rotating in accordance with the drive of the motor (17); A canopy hood 7 installed above the metal rotating plate 6 and having a duct 19 connected to one end thereof; The position of the electrode 5 is controlled by controlling the driving of the motor 17 for operating the electrode holder slide 10, and the rotational speed of the metal rotating plate 6 is controlled by controlling the rotating motor 14 of the metal rotating plate 6. It is composed of a controller 18 for adjusting the.

In the drawings, reference numeral 2 is a body in which the components are installed, 3 is a PVC sealed container installed on the upper body, 11 is a shaft connected to the metal rotating plate 6, and 12 is the shaft 11. ) Is a pulley for transmitting the rotational force of the motor 14, 13 is a V-belt connecting between the pulley (12).

In addition, 15 is a pulley for transmitting the rotational force of the motor 17 to the electrode holder slide 10, 16 is a V belt connecting the pulleys, 19 'is a speed sensor installed in the duct to measure the flow rate of the welding fume. .

On the other hand, the inlet chamber 20 has an inlet flange 21 'is formed in the upper plate 21, the weld fume is introduced from the weld fume generator 1 through the duct 19, the diffuser (drawings) into the inlet flange 21' (Not shown) is installed so that the incoming welding fumes are dispersed into the laboratory.

In addition, one side of the door 23 is installed to allow the laboratory animal to enter and exit the laboratory 24 of the inlet chamber 20, and into the laboratory 24 through which the welding fume is introduced through the door 23. Observed the experimental animals.

In addition, one side of the lower plate 22 is connected to the excrement reservoir (22 ') to collect the excrement of the experimental animal put in the laboratory, the other side of the lower plate 22 is formed with a discharge port 22 "is discharged residual welding fume The outlet 22 "is connected to the hose 25 so that the remaining welding fume is moved toward the fume collector 30.

The fume collector 30 is connected to the outlet 22 " of the inlet chamber 20 and the hose 25, and an inlet 38 through which the residual welding fume flows is installed at one side, and the air introduced from the inlet 38 The filter 36 for filtering the filter 36 is delivered to the suction port 38, and a dirt box 39 for collecting contaminants filtered from the filter 36 is installed below the filter 36.

In addition, the motor 31 and the fan 32 are installed and driven in the upper part of the fume collector 30 so that air is introduced through the suction port.

In addition, the air tank 33, the regulator 34 and the diaphragm 35 is installed to adjust the air pressure, and the controller 37 controls the driving speed of the motor 31 to adjust the amount of intake air.

In the present invention configured as described above, the welding fume generated by approaching the welding rod 5 by the movement of the welding rod holder slider 10 to the metal rotating plate 6 rotated by the motor 14 is collected by the canopy hood 7. After the experiment was put into the inlet chamber 20 of the laboratory 24 by the inlet chamber 20 of the inlet chamber 20 through the duct 19 by the suction force of the fan 32 of the fume collector 30. Will affect animals.

And the welding fume introduced into the laboratory 24 is continuously introduced into the inlet of the fume collector 30 through the hose 25 by the suction force of the fume collector 30, filtered through the filter and then discharged.

The present invention can generate a welding fume of various components by changing the material of the welding rod and the metal rotating plate, it is possible to control the concentration of the welding fume by controlling the thickness and suction flow of the welding rod, it is possible to expose up to 40 experimental animals To enable various experiments.

In addition, by developing and using the base metal as a rotating plate it is possible to prevent the welding rod is melted and attached to the base material.

As described above, the present invention enables the welding fume-related toxicology test to identify the occupational disease of the welding worker, and by analyzing the welding fume, it is possible to develop a welding rod which reduces the harmfulness, and occurs by welding type. Industrial hygienic engineering research such as particle size distribution of welding fume is possible, and it can be used for fume collection performance test of dust mask, and welding fume can be automatically and safely collected without collecting welding fume by performing welding directly. It is a useful invention that protects researchers from causal disclosure.

Claims (2)

A welding rod 5 for generating welding fumes by approaching the metal rotating plate 6 and the metal rotating plate 6 rotating at a predetermined speed, and a canopy hood 7 installed on the metal rotating plate 6 to collect the welding fume; A welding fume generator (1) comprising a controller (18) for controlling the rotational speed of the metal rotating plate (6) and adjusting the position of the welding rod (5); A welding fume inflow flange 21 'is formed at one side of the upper plate 21, an outlet 22 " is formed at one side of the lower plate 22, and a waste storage container is installed at the lower side thereof, and a door for accessing an experimental animal at one side thereof. (23) is provided, the inlet chamber (20) formed by coupling the other end of the duct (19) connected from the canopy hood (7) of the welding fume generator (1) to the inlet flange (21 '); The inlet port 38 "connected to the outlet 22" and the hose 25 through which the residual welding fume is introduced, the filter 36 for filtering the air introduced from the inlet port 38, and the controller 37. A fume collector 30 composed of a fan 32 that rotates according to the driving of the controlled motor 31 to generate suction power; Welding fume toxicity test device, characterized in that consisting of. 2. The welding fume generator (1) according to claim 1, further comprising: a metal rotating plate (6) installed in the sealed container (3) and rotating according to the driving of the motor (14); A welding rod 5 approaching the rotating metal rotating plate 6 to generate a welding fume; A welding rod holder 4 installed on the support 8 after the welding rod 5 is coupled; A welding rod holder slider (10) comprising a movable screw (9) on which the support (8) is installed and rotates according to the driving of the motor (17) to move the support (8); A canopy hood 7 installed above the metal rotating plate 6 and having a duct 19 connected to one end thereof; The position of the electrode 5 is controlled by controlling the driving of the motor 17 for operating the electrode holder slider 10, and the rotational speed of the metal rotating plate 6 is controlled by controlling the rotating motor 14 of the metal rotating plate 6. A controller 18 for adjusting the; Welding fume toxicity test device, characterized in that consisting of.