JP2019166492A - Rock wool spray method - Google Patents

Abstract

To provide a rock wool spray method hardly clogging cotton-blending or dry rock wool in a force feed pipe in spray work time.SOLUTION: In a rock wool spray method of a dry construction method or a semi-dry construction method, an apparatus 10 used for air force feed of dry rock wool is adjusted at a construction site so that an index of expressing kinetic energy of the dry rock wool 11 in the tip vicinity of a force feed passage of the dry rock wool 11 falls within a prescribed range. The rock wool spray method sets the prescribed range being the index of expressing the kinetic energy by determining a spray load in a testing construction by adjusting a wind speed of air used for the air force feed of the dry rock wool 11 in an adjustment of the apparatus 10 used for the air force feed of the dry rock wool 11 at the construction site.SELECTED DRAWING: Figure 3

Description

    The present invention relates to a rock wool spraying method of a dry method or a semi-dry method. In particular, the present invention relates to a rock wool spraying method that is difficult to clog in a dry rock wool pumping route.

  A rock wool spraying method using rock wool, cement and water is used for the purpose of imparting fire resistance, fire resistance, sound absorption, heat insulation, etc. to structural members. As the rock wool spraying method, a dry method, a wet method, and a semi-dry method are known. The dry method and the semi-dry method are known to have an advantage that the bulk density of the coating layer (sprayed rockwool layer) formed by the rockwool spraying method can be reduced as compared with the wet method.

  Rock wool spraying methods using granular rock wool, which is a typical granular fiber, include a dry method, a wet method, and a semi-dry method.

  In the dry method, a dry mixture (mixed cotton) mixed with rock wool and cement is discharged from a nozzle in advance, and at the same time, pressure water is injected from a plurality of fountain ports arranged at the periphery or inside of the nozzle or inside the nozzle. This is a method in which pressure water is injected from a fountain port arranged at the center, and both are mixed and sprayed.

  The wet method uses a spraying coating material composed of a granulated rock wool and cement as a main material and a surfactant and a thickener, and sprays the paste with water added from the nozzle with compressed air. It is.

  The semi-dry method is a method in which granular rock wool and cement are not mixed in advance. For example, granular rock wool is defibrated and crushed by a defibrator, sent quantitatively by a rotary valve, pumped inside the hose by an air blower, and supplied to a spray nozzle. The cement is mixed with water in a mixer to form cement slurry, and is supplied to the spray nozzle through a transport pipe by a slurry pump. Cement slurry is sprayed from the periphery of the nozzle or sprayed from the center of the nozzle, and merged and mixed with rock wool to form a fireproof coating layer (see, for example, Patent Document 1).

  The dry method and the semi-dry method are known to have an advantage that the bulk density of the coating layer (sprayed rockwool layer) formed by the rockwool spraying method can be reduced as compared with the wet method.

JP 2002-348978 A

  At the time of pneumatic feeding of blended cotton in the dry construction method or at the time of pneumatic feeding of rock wool in the semi-dry construction method, the blended cotton or dry rock wool may be clogged in the feeding pipe immediately after the spraying operation is started. For this reason, there has been a demand for a rock wool spraying method that is difficult to clog in the pressure feed pipe during spraying.

  This invention solves the said subject, and it aims at providing the rock wool spraying method in which mixed cotton or dry rock wool is hard to be clogged in a pressure feed pipe at the time of spraying.

  Furthermore, it aims at providing the rock wool spraying construction method which can maintain the bulk density of the rock wool layer formed.

  This invention which solves the said subject is the rock wool spraying construction method of a dry construction method or a semi-dry construction method. The equipment used for pneumatic feeding of the dry rock wool is adjusted at the construction site so that the index representing the kinetic energy of the dry rock wool in the vicinity of the tip of the dry rock wool feeding path falls within a predetermined range.

  As a result, the mixed cotton or dry rock wool is less likely to be clogged in the pressure feeding tube during the spraying operation. Moreover, excessive injection can be suppressed. For example, the bulk density of the formed rock wool layer can be maintained.

  In this invention, Preferably, adjustment of the apparatus used for pneumatic feeding of the dry rock wool in the said construction site adjusts the wind speed of the air used for pneumatic feeding of dry rock wool.

  Thereby, the simplicity in field construction can be maintained.

  In the present invention, preferably, in the test construction, dry rock wool is pneumatically fed, sprayed without mixing water, and the presence or absence of clogging in the dry rock wool pressure feed path is confirmed. An index representing the kinetic energy of the dry rock wool in the vicinity of the tip of the dry rock wool pumping path when no clogging occurs in the wool pumping path is obtained, and the minimum value of the predetermined range is set.

  Thereby, the minimum value can be set easily. By setting the index representing the kinetic energy in the field construction to be equal to or greater than the minimum value, the mixed cotton or the dried rock wool is not easily clogged in the pressure feeding pipe at the time of spraying.

  In the present invention, preferably, in the test construction, dry rock wool is pneumatically fed, mixed with moisture, and sprayed to form a sprayed rock wool layer, the degree of rebound and the volume of the sprayed rock wool layer formed. Check whether the density is the predetermined bulk density, pneumatically feed the dry rock wool, spray without mixing water, no rebound and the tip of the dry rock wool pumping path when the predetermined bulk density An index representing the kinetic energy of dry rock wool in the vicinity is obtained, and the maximum value in the predetermined range is set.

  Thereby, the maximum value can be set easily. By setting the index representing kinetic energy in field construction to a maximum value or less, dust caused by rebounding is suppressed, the bulk density of the formed rock rock wool layer is maintained, and the speed of spray rock rock layer formation is also maintained. .

  An index representing the kinetic energy of the dried rock wool in the vicinity of the tip of the dry rock wool feeding path is the spray load.

  Thereby, an index representing kinetic energy can be easily obtained.

  According to the rock wool spraying method of the present invention, mixed cotton or dry rock wool is not easily clogged in the pressure feeding pipe during spraying.

  Furthermore, the bulk density of the formed rock wool layer can be maintained.

It is an example of the rock wool spraying system used for this construction method. It is an example of on-site construction by this construction method. It is an example of test construction by this construction method. It is an example of test construction by this construction method. It is an example of test construction by this construction method.

~System configuration~
FIG. 1 is an example of a rock wool spraying system used in this construction method. A commonly used spraying system is used. The semi-dry method will be described as an example.

  The rock wool 11 thrown into the rock wool spraying machine 10 is sent to the nozzle 3 through the material hose 9 by the pressurized air sent to the rock wool spraying machine 10 from a blower (not shown). The rock wool spraying machine 10 is equipped with a hopper, a rotary cutter, and a quantitative supply device.

  On the other hand, the cement slurry stored in the storage container 8 is sucked by the pump 7, sent to the ring portion 1, and injected from a plurality of fountain ports 14 attached to the ring portion 1 and arranged on the periphery of the nozzle. The

  The sprayed cement slurry 4 is merged and mixed with the rock wool 5 discharged from the nozzle 3 to form a coating layer.

  In the dry construction method, instead of rock wool, a dry mixture (mixed cotton) in which rock wool and cement are mixed is sprayed, and water is sprayed instead of cement slurry.

-Site construction-
The inventor found that whether or not mixed cotton or dry rock wool is clogged in the pumping pipe during the spraying operation has a correlation with the kinetic energy of the rock wool injected from the tip of the pumping path, and pays attention to an index representing the kinetic energy. did.

  In this construction method, the equipment used for pneumatic feeding of dry rock wool is adjusted at the construction site so that the index representing the kinetic energy of dry rock wool in the vicinity of the tip of the dry rock wool pressure feed path falls within a predetermined range. . This will be described in detail below.

  The dry rock wool includes mixed cotton in the rock wool spraying method of the dry method and rock wool in the rock wool spraying method of the semi-dry method. Water has not been added.

  The vicinity of the tip of the pumping path means a range from 5 m before the pumping end of the dry rockwool pumping path to 2 m from the discharge port after discharging from the tip of the pumping path of the dry rockwool. It is a range from 3 m before the pumping end of the pumping path of the wool to 1 m from the discharge port after discharging from the leading end of the pumping path of the dry rock wool. More preferably, it is a range from 1 m before the pumping end of the dry rockwool pumping path to 1 m from the discharge port after the discharge from the pumping path of the dry rockwool.

  When a spray nozzle is used, the tip of the dry rock wool pressure feed path is the tip (discharge port) of the spray nozzle. When no spray nozzle is used, the dry rock wool pressure feed tube This is the tip of the (pumping hose).

  As an index indicating kinetic energy (hereinafter, also referred to as “kinetic energy index”), a load, stress applied to the member when dry rock wool is applied to a member such as a plate, a rod, or a protrusion, or a stress of the member Preferred examples include displacement (degree of deformation), speed, and the number of rotations (rotational speed) of the blades when the dry rock wool is applied to the blades. Particularly preferably, the dry rock wool is applied directly or indirectly to the upper plate or table of a scale such as an electronic scale, an upper plate scale, an electronic platform scale, an electronic balance or a digital cooking scale, and is displayed at that time. The mass (weight) to be used is used as an index representing the kinetic energy of the dry rock wool near the tip of the dry rock wool feeding path. This spray load is simple in measuring work and apparatus.

  However, as a general rule, an index representing kinetic energy is not measured during construction on site (detailed in the modification).

  Further, the predetermined range will be described in detail separately (see the portions corresponding to FIGS. 3 and 4).

  Equipment used to pneumatically feed dry rock wool is a blower or other blower, as well as a quantitative supply device that supplies dry rock wool into the pumping path, and a device that adjusts the size of the dry rock wool (rotary cutter) Is also included.

  Adjustment of the equipment used for pneumatic feeding of dry rock wool at the construction site adjusts the wind speed of air used for pneumatic feeding of dry rock wool. As a result, an index representing the kinetic energy of the dried rock wool falls within a predetermined range.

  Specifically, it can be performed by adjusting a dial for air blowing setting that can adjust the air speed of a blower or the like, inputting a set value, and the like.

  FIG. 2 is an example of on-site construction. In FIG. 2 to FIG. 5, the plurality of fountain ports 14 attached to the ring portion 1 and disposed on the periphery of the nozzle are omitted.

  In this method, as described above, the wind speed of air used for pneumatic feeding of dry rock wool is adjusted. Other settings are the same as those for test construction (details will be described later).

  Thereafter, a rock wool layer is formed by a general dry method or semi-dry method.

~ Test construction ~
The setting of the index range representing kinetic energy will be described. The minimum and maximum values are set as follows by the test construction.

  First, the setting of the minimum value will be described. FIG. 3 is an example of test construction related to the minimum value setting.

  Without mixing moisture, dry rock wool is pneumatically fed and sprayed. At this time, adding water after spraying the dried rock wool is not included.

  In a plurality of test examples, the occurrence of clogging in the dry rock wool pumping path is confirmed, and an index representing the kinetic energy of the dry rock wool in the vicinity of the tip of the dry rock wool pumping path is obtained.

  From the plurality of test results, the minimum value of the index representing the kinetic energy of the dry rock wool near the tip of the dry rock wool pumping path when no clogging occurs in the dry rock wool pumping path is obtained. Thereby, the minimum value of the predetermined range is set.

  When the index representing kinetic energy is less than the minimum value, clogging is likely to occur in the pumping path.

  At this time, dry lock for about 0.5 to 5 minutes under construction conditions that are the same as or more likely to cause clogging in the dry rock wool pumping route (that is, more severe) than the construction conditions for performing the rock wool spraying method at the site construction. It is preferable to pneumatically feed the wool and confirm that clogging does not occur in the dry rockwool pumping path.

  In other words, as construction conditions, dry rock wool type / size, rock wool sprayer type (model number) / setting, blower type (model number), pumping length (hose length), pumping height, hose inner diameter , Hose material, etc., set as required, especially dry rock wool type / size, rock wool sprayer type (model number) / setting, blower type (model number), pumping length It is preferable to set the length (hose length) and the hose inner diameter to the same or stricter conditions as the construction conditions for performing the rock wool spraying method in the field construction.

  In the above test construction, a part of the spraying system can be omitted or simplified as long as there is no hindrance such as removing the spray nozzle.

  Next, setting of the maximum value will be described. FIG. 4 is an example of test construction related to the maximum value setting.

  The dried rock wool is pneumatically fed, mixed with water, and sprayed to form a spray rock wool layer on the object other than the target structure or member (for example, a plate, a non-purpose steel frame or wall). At this time, adding water after spraying dry rock wool is also included.

  In a plurality of test examples, the degree of rebound (that is, the amount of dust caused by rebound) and whether or not the bulk density of the formed rock rock wool layer is a predetermined bulk density, or whether the spray rock wool layer can be formed quickly. Confirm.

  In parallel with this, in each test example, an index representing the kinetic energy of the dry rock wool in the vicinity of the tip of the dry rock wool pumping path is obtained (see the description corresponding to FIG. 3).

  From several test results, the tip of the dry rock wool pumping path when the dust density due to rebounding is low, the bulk density of the formed rock rock wool layer is the predetermined bulk density, and the spray rock wool layer can be formed quickly The maximum value of the index representing the kinetic energy of dry rock wool in the vicinity is obtained. Thereby, the maximum value in the predetermined range is set.

  In addition, when the parameter | index showing a kinetic energy exceeds a maximum value, it means excess. That is, there is a possibility that problems such as an increase in dust due to rebound, an increase in the bulk density of the formed spray rock wool layer, and a slow formation of the spray rock wool layer may occur.

  By the way, in principle, in field construction, an index representing kinetic energy is not measured (detailed in the modification).

  FIG. 5 is an example of test construction related to wind speed measurement.

  Each test example in which dry rock wool is pneumatically fed and sprayed without mixing the water according to FIG. 3 and each test example in which dry rock wool according to FIG. 4 is pneumatically fed to mix and spray water Corresponding to the above, the wind speed when only the air is blown by the blower is measured, and it is made to correspond to the index representing the kinetic energy.

  In the field construction, the wind speed is adjusted so that the wind speed of the air used for pneumatic feeding of the dry rock wool is within a predetermined range. As a result of making the other conditions the same in the on-site construction and the test construction, the index representing the kinetic energy of the dry rock wool falls within a predetermined range in the on-site construction.

~effect~
In on-site construction, the wind speed of the air used to pneumatically feed the dried rock wool is adjusted so that the index representing the kinetic energy of the dried rock wool falls within a predetermined range.

  Thereby, the parameter | index showing the kinetic energy in on-site construction becomes more than the minimum value, and it becomes difficult to clog cotton blend or dry rock wool in a pressure feeding pipe at the time of spraying work.

  In addition, the index representing the kinetic energy in the field construction is less than the maximum value, dust caused by rebound is suppressed, the bulk density of the formed spray rock wool layer is maintained, and the speed of formation of the spray rock wool layer is also maintained.

  In the test construction, by measuring the spray load, an index representing the kinetic energy of the dried rock wool can be easily obtained.

  In field construction, the air velocity is used as an index that replaces the index representing the kinetic energy of dry rock wool, so that an excessive burden is not imposed on the workers on the site. The above effects can be expected while maintaining simplicity.

~ Modification ~
In this construction method, from the viewpoint of simplicity of on-site construction, in principle, an index representing kinetic energy is not measured in on-site construction.

  On the other hand, an index representing the kinetic energy of the dried rock wool may be measured immediately before the actual site construction under exactly the same conditions as the actual site construction to confirm that it is within a predetermined range. Thereby, it is possible to more reliably suppress defects in the actual construction on site.

  Further, immediately before the actual site construction, the air speed of the air used for pneumatically feeding the dried rock wool may be measured under the same conditions as the actual site construction to confirm that they are within a predetermined range. Thereby, it is possible to more reliably suppress defects in the actual construction on site.

~Example~
As an example of the above test construction, a specific example of setting a minimum value is shown.

  For the test construction, a rock wool sprayer with a built-in blower was used. In addition to the blower, this rock wool sprayer includes a hopper, a rotary cutter, a quantitative supply device, and an inverter device.

  Blended cotton made by Taiheiyo Material Co., Ltd. (trade name: Taiheiyo Spray Coat) that was put into the hopper of a rock wool sprayer, fined by a cutter in the rockwool sprayer, and then pneumatically fed by a blower built in the rockwool sprayer Was applied to the top of the electronic balance approximately perpendicularly so that the distance from the tip of the pressure feeding hose was 1 m, and the load displayed at this time was read to obtain the spray load.

  Adjustment of the wind speed of the air used for pneumatic feeding was performed by obtaining the relationship between the frequency of the inverter device controlling the blower built in the rock wool sprayer and the wind speed and setting the frequency. In addition, the air wind speed was also measured in correspondence with the spray load.

  Whether or not clogging (hose clogging) occurs in the dry rock wool pumping path after one minute has elapsed since the start of discharge, after the mixed cotton is continuously discharged from the tip of the pumping hose under the same conditions after measurement of the spray load It was confirmed. The case where hose clogging occurred was evaluated as “bad” (symbol: x), and the case where hose clogging did not occur was evaluated as “good” (symbol: ◯).

The construction conditions and test results at this time are shown in Table 1.

  In addition, the value of the cutter dial in Table 1 is a dial that controls the number of rotations per unit time (rotation speed) of the built-in cutter in the rock wool spray machine. The larger the value, the faster the rotation speed of the cutter ( The cotton (rock wool grains) in the mixed cotton becomes finer.

Examine test results. When the discharge amount of cotton is M and the spray load is F, it is understood that there is no hose clogging when the following expression (1) is satisfied.
F ≧ 0.080 × M / 5.0 (1)

  In Test Examples 1 to 6, in Test Example 2, the above formula (1) is not satisfied and the hose is clogged, whereas in Test Example 3, the above formula (1) is satisfied and the hose is clogged. Not. Therefore, F = 0.100 is set to the minimum value of the index range representing kinetic energy. The corresponding air wind speed is 22.5 (m / s). Similarly, the shaded value of F in Table 1 is set to the minimum value of the index range representing the kinetic energy in each condition. The air wind speed corresponding to these is the value of the air wind speed shaded in Table 1 corresponding to each.

  According to this, various conditions common to Test Examples 1 to 6 are reproduced by on-site construction, and the equipment is adjusted so that the air wind speed is 22.5 (m / s) or more.

  In Test Examples 7 to 9, in Test Example 7, the above formula (1) is not satisfied and the hose is clogged, whereas in Test Example 8, the above formula (1) is satisfied and the hose is clogged. Not. Therefore, F = 0.085 is set to the minimum value of the index range representing kinetic energy. The corresponding air wind speed is 25.0 (m / s).

  According to this, various conditions common to Test Examples 7 to 9 are reproduced by on-site construction, and the equipment is adjusted so that the air wind speed is 25.0 (m / s) or more.

  In Test Examples 10 to 12, Test Example 10 does not satisfy the above formula (1) and the hose is clogged, whereas Test Example 11 satisfies the above Expression (1) and the hose is clogged. Not. Therefore, F = 0.075 is set as the minimum value of the index range representing kinetic energy. The corresponding air wind speed is 20.0 (m / s).

  According to this, various conditions common to Test Examples 10 to 12 are reproduced by on-site construction, and the device is adjusted so that the air wind speed is 20.0 (m / s) or more.

  In Test Examples 13 to 16, in Test Example 13, the above formula (1) is not satisfied and the hose is clogged, whereas in Test Example 14, the above Formula (1) is satisfied and the hose is clogged. Not. Therefore, F = 0.150 is set to the minimum value of the index range representing kinetic energy. The corresponding air wind speed is 25.0 (m / s).

  According to this, various conditions common to Test Examples 13 to 16 are reproduced by on-site construction, and the equipment is adjusted so that the air wind speed is 25.0 (m / s) or more.

  In Test Examples 17 to 20, in Test Example 17, the above formula (1) is not satisfied and the hose is clogged, whereas in Test Example 18, the above formula (1) is satisfied and the hose is clogged. Not. Accordingly, F = 0.080 is set to the minimum value of the index range representing kinetic energy. The corresponding air wind speed is 20.0 (m / s).

  According to this, various conditions common to Test Examples 17 to 20 are reproduced by on-site construction, and the device is adjusted so that the air wind speed is 20.0 (m / s) or more.

  The specific example of the minimum value setting has been described above. Similarly, the maximum value is also set.

DESCRIPTION OF SYMBOLS 1 Ring part 2 Blower 3 Nozzle 4 Spray slurry 5 Spray rock wool 6 Suction hose 7 Pump 8 Storage container 9 Material hose 10 Rock wool sprayer 11 Rock wool 12 Cement slurry 13 Anemometer 14 Fountain

Claims (5)

In rock wool spraying method of dry method or semi-dry method,
The equipment used for pneumatic feeding of dry rock wool is adjusted at the construction site so that the index representing the kinetic energy of dry rock wool in the vicinity of the tip of the dry rock wool pumping path falls within a predetermined range. Rock wool spraying method. The rock wool spraying method is characterized in that the adjustment of the equipment used for pneumatic feeding of the dry rock wool at the construction site adjusts the wind speed of the air used for pneumatic feeding of the dry rock wool. In test construction,
Air dry dry rock wool, spray without mixing water,
Check for clogging in the dry rockwool pumping route,
Obtain an index representing the kinetic energy of the dry rock wool near the tip of the dry rock wool pumping path when clogging does not occur in the dry rock wool pumping path,
The minimum value of the said predetermined range is set. The rock wool spraying method of Claim 1 or 2 characterized by the above-mentioned. In test construction,
Pneumatically feed dry rock wool, mix moisture, spray, form a rock rock wool layer,
Check whether the degree of rebound and the bulk density of the formed spray rock wool layer is a predetermined bulk density,
Air dry dry rock wool, spray without mixing water,
Obtain an index representing the kinetic energy of dry rock wool near the tip of the dry rock wool pumping path when there is no rebound and a predetermined bulk density,
The rock wool spraying method according to claim 1 or 2, wherein a maximum value in the predetermined range is set. The rock wool spraying method according to any one of claims 1 to 4, wherein the index representing the kinetic energy of the dry rock wool in the vicinity of the tip of the dry rock wool pumping path is a spray load.