JP3788859B2 - Electrostatic conductive respirator - Google Patents

Description

[0001]
[Technical field to which the invention belongs]
The present invention relates to an electrostatically conductive respirator.
[0002]
[Prior art]
An electrostatic conduction type respirator is designed to prevent static electricity from being stored in the respiratory system and human body by allowing each component of the respiratory system to conduct electricity, flow to the human body wearing the respiratory system, and ground the human body. Thus, it can be used as a safety tool for preventing an explosion accident caused by static electricity in a gas environment that is likely to explode. This electrostatic conduction type respirator is used as a respirator suitable for work requiring countermeasures against static electricity in an environment where there is a risk of explosion, such as a flammable substance such as a chemical factory or an oil refinery factory.
[0003]
In addition, according to the static electricity safety guidelines (prepared by the Institute of Industrial Safety, Ministry of Labor), the leakage resistance value of the human body is 10 in order to prevent the occurrence of sparks due to electrification of the human body.⁸ It is specified as Ω or less. When touching the low-voltage distribution line to get an electric shock, set the leakage resistance to 10^Five Ω or more, 10⁸ Ω or less is desirable. Therefore, all leakage resistance values including respiratory organs, human bodies and shoes are set to 10^FiveΩ or more, 10⁸Must be Ω or less. Furthermore, the charged potential of the human body needs to be 100 V or less. The antistatic antistatic shoes actually used (hereinafter abbreviated as "electrostatic shoes") are 10⁷ Ω or less, and the electrical resistance value of the respiratory organ is 10^FiveΩ-10⁷Ω is desirable.
[0004]
In typical prior art, the facepiece to be worn on the face has elasticity such as an annular rubber having elasticity that comes into close contact with the face and comes into contact with the face in order to achieve airtightness with the face. A seal member having the following is used. The seal member is electrically conductive and is electrically connected to the respiratory components. As a result, static electricity generated in each component of the respiratory system is grounded from the human body through the face from the conductive seal member, and static electricity can be prevented from being charged.
[0005]
The problem with this prior art respirator is that the electrical resistance of a rubber seal member varies greatly with ambient temperature. For example, 1 × 10 at 20 ° C⁶Ω, 1 × 10 at 0 ° C⁷In general, when it changes by 20 ° C., its electric resistance value changes by one digit. Further, the electric resistance value varies depending on the amount of conductive material added to the rubber material. If the electrical resistance value of the seal member becomes too high, static electricity cannot be released sufficiently and the static electricity may be charged. Moreover, if the electrical resistance value is too low, there is a risk of electric shock of the human body. Therefore, the energization performance of the respiratory organ is unstable. Therefore, it is necessary to determine the electrical resistance value of the faceplate seal member in anticipation of temperature changes and fluctuations in the amount of mixed conductive material.
[0006]
In this prior art, it is also troublesome to check whether or not the desired energization performance is obtained. In order to allow static electricity to flow from the respiratory organ to the human body, electricity flows from the above-described conductive sealing member of the face body to the human body. Electricity flows over the entire contact area of the portion that contacts the face of the seal member. Therefore, the current value through which electricity flows varies depending on the contact area between the seal member and the face. In particular, one of the contact rods having an outer diameter of about 2 mm of the insulation resistance meter is brought into contact with a part of the seal member, and the other contact rod is brought into contact with a component other than the face plate of the respiratory organ, for example, a metal part of the pressure vessel. Even if the electrical resistance value is measured, the electrical resistance value is 10⁷ At about Ω, since the contact area between the seal member and the contact rod is small, it cannot be said to be a true value of the electrical resistance value in the actual use situation of the respiratory organ. Also 10⁸ Cannot determine whether to use beyond Ω. Therefore, in the past, for inspection, a dummy head model having a conductive face shape of the human body is prepared and prepared in advance, and the face model is attached to the face of the head model and sealed. It is necessary to measure the electrical resistance value in a state where the member is in surface contact with the face. Therefore, there is a problem that an inspection jig such as a human head model is required as described above.
[0007]
In the prior art, the pressure vessel of the respiratory organ including the pressure vessel and the backpack are covered with a cover using a conductive antistatic material. This prevents the occurrence of sparks from discharge and impact from metal parts. In order to operate the manual knob for opening / closing the closing valve fixed to the pressure vessel to angular displacement, the cover is provided with an opening for inserting a hand and a forearm. Therefore, through this opening, metal parts in the vicinity of the shut-off valve are exposed, or a coating layer such as an epoxy resin covering the metal pressure vessel main body is exposed, which may cause a spark due to static electricity.
[0008]
[Problems to be solved by the invention]
The purpose of the present invention is to stabilize the conductive performance for leaking static electricity from the respiratory organ through the human body and to make it easy to check the conductive performance for preventing static electricity. It is to provide a conductive respirator.
[0009]
[Means for Solving the Problems]
  The present invention is provided on a face body at a position where it contacts the face when the face body is worn.MetalConductive contact pieces;
  MaskInsideOne end is connected to the contact piece, and the other end is connected to the conductive connection port of the face piece connecting the supply valve.^Five-10⁷A fixed resistor having an electrical resistance value of Ω,
  Respirator electrical resistance value is 10^Five-10⁷Ω andAnd
  The one end and the other end of the fixed resistor are respectively connected to two conductive wires covered with a covering layer made of an electrically insulating material,
  Covered by an electrical insulator across the one end of the fixed resistor and one conductor and across the other end and the other conductor;
  The one conducting wire is connected to a contact piece, and the other conducting wire is connected to a connection port of a face piece connecting the supply valve.It is an electrostatic conduction type respirator characterized by this.
[0010]
  According to the present invention, the conductive contact piece is attached to the face piece at a position where the face piece contacts the face of the human body, and the contact piece is connected to the respiratory component via a fixed resistor provided on the face piece. Connected and electrically connected. At least the surface of the contact piece is conductive,MoneyGenusTheIt is sufficient if the applied voltage is 100 V or less and an electric resistance of 10 Ω or less can be measured with a contact rod of an insulation resistance meter. The contact piece has a shape that locally contacts the face, and may have a button-like shape with a diameter of about 0.5 to 1 cm, for example.
[0011]
Electric resistance value is 10^Five When it is less than Ω, when the conductive part of the respirator comes into contact with a commercial power source of 100 to 400 V, for example, the wearer who is wearing the respirator is not wearing an electrostatic shoe. When you get an electric shock, it is dangerous. In addition, it is effective to prevent the electric shock to be provided on the face body as close as possible to the human body. The electrical resistance value from the respiratory organ to the electrostatic shoe or foot is 10⁸ If the value exceeds Ω, static electricity does not flow easily, and the respiratory organ is charged with static electricity, so that antistatic performance cannot be achieved. The static electricity generated in the respiratory organ flows from the respiratory organ through the human body, through the electrostatic shoes worn by the wearer of the respiratory organ, to the static electricity prevention floor (hereinafter referred to as a conductive floor). The electric resistance value of the electrostatic shoe is, for example, 10^Five-10⁷Ω. The fixed resistor provided on the face body needs to be set so as to have such an electric resistance value. This allows grounding to escape without static electricity being charged to the respiratory organ.
[0012]
The fixed resistor can be a commercially available fixed resistor such as a metal film resistor, a carbon resistor and a winding resistor, and such a fixed resistor can be used even if the ambient temperature changes. Its electric resistance value is stable. Accordingly, the electrostatic conductive performance is stabilized.
[0013]
Before inspecting the electrostatic conduction function before using the Respirator, place the Respirator on an electrical insulator and place one contact rod of the insulation resistance meter against the contact piece, and the other contact rod. The electrical resistance value is obtained by applying to the cover, which is the component of the respiratory device farthest from the face piece. According to the present invention, the contact piece is in local contact with the face, and the electrical resistance value can be measured without using an inspection jig such as the head model described above in relation to the prior art. Easy to check. Moreover, the fluctuation | variation of the electrical resistance value of an electroconductive sealing member may be large.
[0014]
A connection port of a supply valve such as a pressure demand valve or a demand valve described later is detachably or fixedly connected to the conductive connection port of the face piece. The other end of the fixed resistor is connected to the conductive connection port of the face piece. As a result, the other end of the fixed resistor is electrically connected to the respiratory apparatus.
[0015]
In one embodiment of the present invention, all of the face pieces are made of a conductive material, and the supply valve is also made of a conductive material.
[0017]
According to the present invention, both ends of the fixed resistor are respectively connected to the conductive wires having the electrically insulating coating layer, and the synthetic resin adhesive, for example, an epoxy resin or the like, extends over both ends of the fixed resistor and the exposed conductive wires. Covered with. Therefore, it is possible to prevent the fixed resistor and its metal connection portion from being corroded or short-circuited by water vapor and water droplets contained in the exhaled gas, etc., and a stable electric resistance value can be maintained over a long period of time.
[0018]
In the invention, it is preferable that the fixed resistor is disposed in the vicinity of an inlet to which intake gas to the face body is supplied.
[0019]
In accordance with the present invention, the fixed resistor is located near the inlet of the intake gas, i.e., near the connection to the facepiece supply valve, which is a dry, low-humidity gas, and thus the fixed resistor and The metal portion is not corroded and can maintain a stable electric resistance value.
[0020]
Further, in one embodiment of the present invention, the intake gas in the pressure vessel is guided to the pressure reducing valve from the blocking valve attached to the pressure vessel and can be opened and closed by operating a manual knob, and then reduced through the intermediate pressure hose. Reduce the pressure to about atmospheric pressure with a supply valve such as a pressure demand valve or demand valve, and supply it to the face.
The pressure vessel is detachably attached to the backpack made of metal supported on the back of the wearer,
The intermediate pressure hose is configured by surrounding an outer peripheral surface of a rubber pipe main body with a metal cover and surrounding an outer surface of the metal cover with rubber having antistatic performance,
The other conducting wire is connected to the metal sheath through a connection port of a face piece, a connection port of a supply valve that is detachably or fixedly connected to the connection port of the face piece, and a conductive supply valve. And
The end portion of the covering body near the pressure reducing valve is connected to one end portion of the connecting conductor and is electrically connected to the pressure indicator lead pipe and the pressure indicator,
The connecting wire is connected to a backpack and a cover.
[0021]
According to the present invention, the intermediate pressure hose, which is a flexible pipe that supplies intake gas from the pressure reducing valve to the face body, is reinforced on the outer peripheral surface of the rubber pipe body by a metal cover, for example, a metal net. The contact piece is connected to the fixed resistor through one conductive wire, and the other conductive wire is connected to the end portion of the intermediate pressure hose near the face body through the conductive supply valve. Near the pressure reducing valve of the intermediate pressure hose, the end of the covering is connected to one end of a connecting wire, for example, a stranded wire made of a plurality of flexible wires, and the connecting wire is made of metal. Connected to backpack and conductive cover.
[0022]
Further, the connecting lead is connected to a coiled metal sheath that surrounds and protects the pressure indicator lead pipe that guides the intake gas to the pressure indicator that detects the pressure of the intake gas filled in the pressure vessel. ing.
[0023]
Further, the present invention introduces the suction gas in the pressure vessel from the blocking valve attached to the pressure vessel, which can be opened and closed by the operation of a manual knob, to the pressure reducing valve to reduce the pressure, and through the intermediate pressure hose and the supply valve, the face body To supply
The pressure vessel is an electrostatically conductive respirator that is removably attached to a metal back supported on the back of the wearer.
A flexible cover made of a conductive sheet, covering a pressure vessel, a blocking valve, a pressure reducing valve, and a backpack, and having an openable / closable opening near the position of a manual knob of the blocking valve, and a corona discharge function And a conductive sheet body, which is connected to the opening, is fixed to the inside of the cover, and is inserted inside the opening to operate the manual knob of the closing valve. A flexible bag,
The cover is an electrostatically conductive respirator characterized in that it is electrically connected to the wearer.
[0024]
According to the present invention, the pressure vessel, the blocking valve, the pressure reducing valve, and the backpack are covered with the conductive flexible cover so that the manual knob for opening and closing the blocking valve can be operated. In addition, in the opening formed in the cover, a pocket-shaped flexible bag body made of a sheet body having a corona discharge function or a conductive sheet body is arranged continuously to the inside of the cover. Therefore, the operator can insert a hand or a part of the forearm through the opening into the bag and operate the manual knob to rotate the operation knob by about 180 degrees, for example, to open or close the valve. The cover is electrically connected to the wearer, i.e., the human body, and is grounded to the conductive floor or the ground via electrostatic shoes.
[0025]
In this way, when the pressure vessel has a structure in which an electrically insulating coating layer such as an epoxy resin is formed on the outer peripheral surface of a metal pressure vessel body, even if static electricity is charged on such a coating layer, Even if the container is charged, since the cover is grounded through the human body, it is in an electrostatic shielding state, and the generated static electricity is not discharged to the outside.
[0026]
Furthermore, according to the present invention, as described above, the opening is provided with a bag body, and this bag body has a corona discharge function or is electrically conductive, so that the opening has been greatly opened. However, the bag body prevents the components such as the pressure vessel, the blocking valve, the pressure reducing valve, and the backpack from being exposed to the outside. In this way, the antistatic function can be reliably achieved, and the discharge of charged static electricity and thus the occurrence of sparks can be reliably prevented.
[0027]
The corona discharge is a local discharge in which only a portion where the electric field is concentrated due to an unequal electric field causes ionization, and light emission is accompanied by a weak breakdown sound. Since the corona discharge has a low discharge energy density, the probability of causing an electrostatic disaster or failure is low, and the corona discharge generated by the fibrous conductor has a very low probability of becoming an ignition source of the combustible substance. The sheet body having a corona discharge function of the bag body may be a woven fabric containing conductive fibers. Further, when the bag body is made of a conductive sheet body, the bag body is electrically connected to the cover body by being fixed to the cover body, and thus is electrically connected to the human body.
[0028]
In one embodiment of the present invention, the backpack is made of a material having a corona discharge function or a conductive material, and a backpack band to be worn by the wearer is attached.
The cover is formed with an opening through which the back band is inserted.
[0029]
According to the present invention, the back strap attached to the metal back strap is at least partially exposed from the cover, and the back strap is made of a material having a corona discharge function, thereby preventing electrostatic charging. . Alternatively, when the back band is made of a conductive material, the back band is electrically connected to prevent the charging.
[0030]
Further, the present invention introduces the suction gas in the pressure vessel from the blocking valve attached to the pressure vessel, which can be opened and closed by the operation of a manual knob, to the pressure reducing valve to reduce the pressure, and through the intermediate pressure hose and the supply valve, the face body To supply
The pressure vessel is an electrostatically conductive respirator that is removably attached to a metal back supported on the back of the wearer.
A flexible cover made of a conductive sheet, covering a pressure vessel, a blocking valve, a pressure reducing valve, and a backpack, and having an openable / closable opening near the position of a manual knob of the blocking valve, and a corona discharge function And a conductive sheet body, which is connected to the opening, is fixed to the inside of the cover, and is inserted inside the opening to operate the manual knob of the closing valve. A flexible bag,
A conductive contact piece provided on the face body at a position in contact with the face when the face body is worn,
Provided on the face plate, one end is connected to the contact piece, and the other end is electrically connected to the pressure reducing valve, the blocking valve, the pressure indicator air guide tube, the pressure indicator, the intermediate pressure hose, the supply valve and the cover. 10^Five-10⁷An electrostatic conductive respirator comprising a fixed resistor having a resistance value of Ω.
[0031]
According to the present invention, the combination of the contact piece and the fixed resistor can stabilize the electrostatic conduction performance by preventing the change depending on the ambient temperature as described above, and can also stabilize the electrostatic conduction of the respiratory organ. The performance can be easily checked with an insulation resistance meter, and the bag for operating the manual knob of the closing valve is fixed to the cover opening, so that the opening remains open. Even in this state, it is ensured that the static electricity of components such as the pressure vessel enclosed by the cover is prevented from being charged, and the discharge due to static electricity is prevented to prevent the occurrence of sparks.
[0032]
Further, in one embodiment of the present invention, the face piece has an annular sealing member having elasticity,
The seal member extends from the lower part of the facial chin to the lower front part of the chin,
The contact piece is arranged at the lower front part of the seal member.
[0033]
According to the present invention, when the face body is mounted on the face of the wearer, the contact piece comes into contact with the lower front part (the chin triangle) of the jaw of the face, and electrical conduction with the human body is achieved. The The seal member is arranged from the lower part of the jaw to the lower front part of the jaw where the contact piece is arranged, that is, the seal member is arranged inward so that the airtightness of the face piece is achieved. As a result, even if the contact piece is attached to the seal member, the airtightness between the seal member and the face is reliably maintained, and the gas in the face does not leak to the outside in the vicinity of the contact piece. There is no risk of intruding into the face.
[0034]
The invention is implemented not only in connection with an open respirator, but also in connection with a closed respirator that circulates and absorbs carbon dioxide in the exhaled breath.
[0035]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is a cross-sectional view in which a part of a face body 2 of an electrostatic conductive respirator 1 according to an embodiment of the present invention is cut away. The face body 2 is attached to the face 4 of the human body 3 to which the electrostatic conductive respirator 1 is attached.
[0036]
FIG. 2 is a diagram showing the overall configuration of the electrostatic conductive respirator 1. The pressure vessel 5 filled with compressed air is detachably attached to a metal plate 7 of a backpack 6 made of a metal material such as stainless steel. The pressure vessel 5 may be entirely made of a metal material, or may have a configuration in which an electrically insulating coating layer such as an epoxy resin is formed on the outer peripheral surface of a metal pressure vessel body. The metal pressure vessel main body of the pressure vessel 5 is made of, for example, aluminum, and the thickness of the coating layer formed on the outer peripheral surface thereof is, for example, 3 to 4 mm. The backpack 6 is provided with a backband 8 made of an antistatic cloth containing carbon fiber, and a band 9 attached to the abdomen or waist made of a similar material. Synthetic resin buckles 10, 11, and 12 are attached to these bands 8 and 9, and these buckles 10, 11, and 12 are relatively small in size, and their charge amount is very small. There is no risk of igniting the combustible material.
[0037]
A blocking valve 14 is attached to the lower mouth portion 13 of the pressure vessel 5, and a pressure reducing valve 15 is connected to the blocking valve 14. The pressure reducing valve 15 is connected to the face body 2 through a flexible intermediate pressure hose 16 and a pressure demand valve 22 which is a supply valve. A cover 17 made of a conductive sheet having flexibility covers the pressure vessel 5, the closing valve 14, the pressure reducing valve 15, the backpack 6 and the like.
[0038]
The blocking valve 14 and the pressure reducing valve 15 are made of metal, and the manual knob 18 of the blocking valve 14 is made of an electrically insulating synthetic resin.
[0039]
FIG. 3 is a simplified side view of the electrostatically conductive respirator 1. The backpack 6 covered with the cover 17 is put on the back of the wearer, and the backpack 6 is worn on the back with a backband 8 from the shoulder. The face body 2 is attached to the face 4 of the wearer 3 as described above.
[0040]
FIG. 4 is a system diagram showing the gas flow of the electrostatic conduction type respirator 1. The high pressure intake gas in the pressure vessel 5 is, for example, 150 to 300 kgf / cm.² The intake gas is guided to the pressure reducing valve 15 and is about 6 kgf / cm.² The pressure is reduced to The intake gas from the pressure reducing valve 15 is guided to the pressure demand valve 22 through the intermediate pressure hose 16, is decompressed to near atmospheric pressure, and is guided to the face body 2 through the pressure demand valve 22. The pressure demand valve 22 has a pressure demand function for keeping the pressure in the face piece 2 at a positive pressure, and operates according to breathing. The exhaled air is dissipated into the atmosphere through the pressure demand type exhalation valve 23.
[0041]
Further, in order to be able to detect the pressure of the intake gas in the pressure vessel 5, a pressure indicator 24 is connected via a pressure reducing valve 15 via a flexible pressure indicator lead tube 25. The pressure indicator lead pipe 25 also has a pressure of intake gas in the pressure vessel 5 that is a starting set pressure, for example, 30 kgf / cm.²An alarm device 26 is connected to generate an alarm sound when the number is decreased.
[0042]
FIG. 5 is a simplified diagram showing a path through which static electricity leaks from the electrostatic conductive respirator 1 of the present invention. According to the invention, a conductive contact piece 27 and a fixed resistor 28 are provided in connection with the face piece 2. It is assumed that the human body 3 is put on the electrostatic shoes 29 and walks on the floor 30 for preventing static electricity. The electric resistance value of the electrostatic shoe 29 is 10^Five-10⁷Ω. In order to allow the static electricity of the respirator 1 to escape smoothly to the grounded conductive floor 30, the electrical resistance value of the electrostatic leakage path L1 between the electrostatic shoe 29 and the cover 17 where the electrostatic shoe 29 is furthest away is 10⁸Must be Ω or less. Therefore, the electrical resistance value of the static electricity leakage path L2 between the contact piece 27 attached to the face piece 2 and the cover 17 is 10⁷Ω or less.
[0043]
6 is a front view of the face piece 2, FIG. 7 is a side view of the face piece 2, and FIG. 8 is a partial cross-sectional view seen from the side of the face piece 2. With reference to these drawings and FIG. 1 described above, in the face body 2, a front plate 33, which can be called an eyepiece having translucency, is fixed to the frame body 32. A fixture 30 for fixing the pressure demand valve 22 and an exhalation valve 23 are attached. The conductive connection port 117 of the pressure demand valve 22 is detachably fitted and attached to the conductive connection port 116 of the fixture 30. The fixture 30 of the face piece 2, the pressure demand valve 22, the seal member 35 of the face piece 2, etc. are conductive, and the metal cover 66 (see FIG. 13 to be described later) of the intermediate pressure hose 16 is connected to the pressure demand valve 22. It is electrically connected to the connection port 117. An intermediate pressure hose 16 is connected to the pressure demand valve 22. The frame 32 is attached with a lace 34 for removably fixing the frame 32 to the head of the human body 3.
[0044]
A base end portion of an annular seal member 35 is fixed to the frame body 32. The sealing member 35 is made of a conductive rubber having soft elasticity, and comes into contact with the upper surface of the nose 36 of the face 4 of the human body 3, the cheek (chin) and the chin (chin) 37, and comes into close contact with each other. Keep airtight. The lower portion of the seal member 35 is a seal portion lower portion 38 that elastically contacts the lower surface of the lower portion (a chin triangle) 37a of the jaw 37, and a seal that extends from the lower portion 38 of the seal portion to the lower front portion (the chin) 37b of the jaw 37. Subordinate front part 39. The lower part 38 and the lower front part 39 of the seal part extend right and left along the jaw 37. An attachment portion 40 is connected to the outside of the seal portion lower portion 38 and the seal portion lower front portion 39, and the attachment portion 40 is fixed to the lower portion of the frame body 32. Thus, the nose and mouth of the face 4 face the space 41 in an airtight manner by the inner mask 35a made of conductive rubber having soft elasticity. The peripheral edge portion of the inner mask 35a constitutes the aforementioned sealing member 35. The expiratory valve 23 communicates with the space 41.
[0045]
FIG. 9 is a front view showing a part of the inside of the face piece 2 viewed from the arrow IX in FIG. In the jaw 37 of the seal member 35, the conductive contact piece 27 according to the present invention is fixed to the seal portion lower front portion 39 that achieves airtightness inward than the seal portion lower portion 38.
[0046]
FIG. 10 is a cross-sectional view seen from the side of the contact piece 27 and its vicinity. This contact piece 27 is integrally extended from the center of the flat disc-shaped contact portion 43 that contacts the lower front portion 37 b of the jaw 37 and the lower front portion 39 of the seal member 35. A flat washer 121 that is sequentially inserted into the shaft portion 44 on the side opposite to the abutting portion 43 with respect to the shaft portion 44 that performs the sealing portion lower front portion 39, a connection terminal 61 that is a crimp terminal, a spring washer 122, And a nut 45 having an internal thread that engages with an external thread engraved on the shaft portion 44. By attaching the face piece 2 to the face 4 in this manner, the contact portion 43 of the contact piece 27 can elastically contact the lower front portion 37 b of the jaw 37. In addition, the airtightness between the space 41 and the outside is achieved by the seal member lower portion 38 being elastically in close contact with the lower portion 37 a of the jaw 37 outside the lower front portion 39 of the seal member 35. Therefore, there is no possibility that the airtightness is lowered by attaching the contact piece 27 to the lower front portion 39 of the seal portion.
[0047]
FIG. 11 is a front view showing the entire configuration of the resistance member 47 including the fixed resistor 28, and FIG. 12 is a sectional view of the vicinity of the fixed resistor 28. The fixed resistor 28 may be, for example, a metal film resistor, a carbon resistor, a winding resistor, or the like. The entire shape of the fixed resistor 28 is formed in a substantially cylindrical shape, and a pair of lead wires 49 and 50 are fixed on the axis thereof. One end portion of the lead wire 49 is fixedly connected to the lead wire 53 of the one covered lead wire 51 by a caulking connection piece 54. The other end portion of the other lead wire 50 is fixedly connected to the lead wire 55 of the other covered lead wire 52 by a caulking connection piece 56. The covered conductor 51 is configured by covering the conductor 53 with a coating layer 57 made of an electrically insulating material such as vinyl chloride. The other covered conductor 52 is also configured by covering the conductor 55 with a covering layer 58 made of an electrically insulating material such as vinyl chloride.
[0048]
The conductive wires 53 and 55 exposed from the fixed resistor 28, the lead wires 49 and 50, the caulking connection pieces 54 and 56 and the covering layers 57 and 58 are covered with an electrical insulator 59. The electrical insulator 59 may be, for example, a synthetic resin adhesive such as an epoxy resin. The electrical insulator 59 covers the end portions of the coating layers 57 and 58. The heat-shrinkable synthetic resin cylindrical tube 60 covers the covering layers 57 and 58 at a position far from the electrical insulator 59 and the electrical insulator 59. The total length a1 including the fixed resistor 28, the lead wires 49, 50 and the caulking connection pieces 54, 56 is, for example, about 35 mm.
[0049]
Connection terminals 61 and 62, which are crimp terminals having circular connection holes, are connected to the conductors 53 and 55 at the ends of the conductors 53 and 55 opposite to the fixed resistor 28. The shaft portion 44 is inserted into the connection hole of one of the connection terminals 61 and is fastened and fixed with the nut 45 between the shaft portion 44 and the lower front portion 39 of the seal portion. As a result, the connection terminal 61 is electrically connected to the contact piece 27. As is apparent from FIGS. 1, 8, and 9, the resistance member 47 is disposed between the sealed front portion 39 and the attachment portion 40, and the face body 2 is attached to the face 4 of the human body 3. It is disposed at a position that does not contact the face 4 and that does not hinder the sealing function of the sealing member 35. Further, the resistance member 47 is disposed in the vicinity of the inlet 64 where the dried intake gas from the intermediate pressure hose 16 is introduced into the space 41 of the face piece 2 through the pressure demand valve 22. Therefore, even if the water tightness due to the electrical insulator 59 and the cylindrical tube 60 is insufficient, the fixed resistor 28 of the resistance member 47, the lead wires 49 and 50, the caulking connection pieces 54 and 56, and the lead wire 53. , 55 are prevented from coming into contact with water vapor and water droplets, thereby preventing oxidative corrosion or short-circuiting.
[0050]
FIG. 13 is a cross-sectional view perpendicular to the axis of the intermediate pressure hose 16. The intermediate pressure hose 16 is reinforced on the outer peripheral surface of a rubber tube main body 65 by a covering 66 made of a conductive metal net, and further covered with a rubber covering layer 118 having an antistatic performance. It has the structure made. As clearly shown in FIG. 1, the connection terminal 62 is connected to the connection terminal 62 of the covered conductor 52 of the resistance member 47 by a mounting piece 67 and a combination of bolts and nuts 68. The connection port 116 is conductive as described above, and the connection port 117 of the pressure demand valve 22 is fitted and electrically connected to the connection port 116, and the connection port 117 is connected to the cover 66. Electrically connected. In this way, the contact piece 27 is electrically connected to the covering 66 of the intermediate pressure hose 16 through the pressure resistor 22 via the fixed resistor 28. The covering layer 118 may be made of conductive rubber. Further, the tube body 65 may be made of conductive rubber.
[0051]
FIG. 14 is a simplified perspective view showing a connecting lead wire 69 that is a ground wire used for releasing static electricity and a connection state of the connecting lead wire 69. A connecting wire 69 is fixed to the cover 66 of the intermediate pressure hose 16 by an annular caulking piece 70 at the other end near the pressure reducing valve 15. The connecting wire 69 is a stranded wire composed of a plurality of flexible wires, and the whole has flexibility.
[0052]
FIG. 15 is a cross-sectional view of the vicinity of the caulking piece 70. One end of the connecting wire 69 is pressed against the other end of the metal cover 66 by the caulking piece 70 to be electrically connected. The metal covering 66 is in contact with the metal fitting at the end of the intermediate pressure hose 16. The intermediate portion of the connecting wire 69 is pressed against the metal fitting at the end of the intermediate pressure hose 16 by the caulking piece 70 to be electrically connected. The end portion of the connecting lead wire 69 is an end portion of the pressure indicator lead tube 25 in the vicinity of the closing valve 14 side, and the end portion of the coiled covering 71 for protecting the lead tube 25 is annularly caulked. Connected by the piece 72.
[0053]
FIG. 16 is a cross-sectional view showing a configuration in which the connecting lead wire 69 is connected to the metal coiled covering 71. The pressure indicator air guide tube 25 is configured such that the outer periphery of a flexible synthetic resin air guide tube body 73 is surrounded by a coil-shaped covering body 71. The end portion of the air guide pipe body 73 is fitted with a pipe joint 75 attached to a connection port 74 of the pressure reducing valve 15 fixed integrally with the blocking valve 14, and is kept airtight by a metal caulking ring 76. And fixed. The coiled covering 71 is in electrical contact with the caulking ring 76. The caulking ring 76 is electrically connected to the metal pressure reducing valve 15 via the metal pipe joint 75. As shown in FIG. 17, the end of the coil-shaped covering 71 is caulked and fixed together with a connecting lead wire 69 by a caulking piece 72 made of, for example, aluminum.
[0054]
The connecting wire 69 is then bound to the backpack 6 by an annular restraining piece 78 as shown in FIG. As a result, the connecting lead wire 69 is electrically connected to the backpack 6. A connection terminal 79 is connected to the other end of the connecting wire 69. A circular attachment hole 80 is formed in the connection terminal 79. Inside the conductive cover 17, a small screw 82 is inserted through the insertion hole 83 at the corner 81, the attachment hole 80 of the connection terminal 79 is inserted, and the nuts using the washers 84, 85 and the spring washer 86 are used. Fastened by 87 and fixed. Thus, the connecting lead wire 69 is electrically connected to the conductive cover 17.
[0055]
18 is a view showing the conductive cover 17 turned upside down, FIG. 19 is a view showing the cover 17 turned upside down, and FIG. 20 is a view showing details of the corners of the cover 17 turned upside down. FIG. The cover 17 is basically composed of a conductive sheet body 88, and the front side thereof, that is, the side opposite to the backpack 6 with respect to the pressure vessel 5, is substantially hermetically configured to be opened and closed by the operation piece 90 of the slide fastener 89. It is formed in a bag shape. In FIG. 18, the operation piece 90 is located at the lower end portion of the cover 17 and is in a closed state. In order to open the cover 17, the operation piece 90 may be lifted and displaced in FIG. 18, 19, and 20, the sheet body 88 of the cover 17 is machined, and the seam that is machined is indicated by a broken line. As shown in FIG. 20, the sheet body 88 of the cover 17 is machined so as to form curved corners at reference numerals 94 to 97 at the respective corners.
[0056]
As clearly shown in FIG. 19, the cover 17 is formed with slit-shaped notches 91, 92, 93 for inserting the back negative band 8. These notches 91, 92, and 93 are almost exactly inserted through the back straps 8 and 9, and no space is created. As a result, no gaps are left in the notches 91, 92, 93. Therefore, there is no possibility that discharge of static electricity to an external member will occur.
[0057]
Further, according to the present invention, the sheet body 88 of the cover 17 is formed with an opening 101 that is a slit-shaped notch corresponding to the position of the manual knob 18 of the closing valve 14. In the vicinity of the lower portion of the sheet body 88 of the cover 17, as shown in FIG. 19, the above-described manual knob 14 of the closing valve 18 is elongated vertically so that it can be operated with one hand. A slit-shaped opening 101 is formed. The length a2 of the opening 101 may be 20 cm, for example.
[0058]
FIG. 21 is a simplified cross-sectional view of fastener 89. The cover portion 98 of the sheet body 88 covers the fastener 89 outward (downward in FIG. 21), thereby preventing the fastener 89 from being exposed outward. The fastener 89 is made of an electrically insulative synthetic resin material and covered with a conductive material, thus providing a countermeasure against static electricity.
[0059]
FIG. 22 is a plan view showing a part of the sheet body 88 of the cover 17 in the vicinity of the corner 96 in FIG. The corners 81 of the sheet body 88 are machined as indicated by broken lines. The corner portion 81 is formed with an insertion hole 83 as described above with reference to FIG. In the corner portion 81, the sheet body 88 is doubly arranged, so that the connection and electrical conduction of the connecting conductor 69 are reliable. The corner 81 is inside the cover 17.
[0060]
FIG. 23 is a perspective view of the flexible bag body 102 attached to the opening 101 as viewed from the inside of the cover 17. The bag body 102 is formed by folding a long and narrow sheet body at a fold line 103, and both sides thereof are perforated by perforations 104 and 105 as indicated by broken lines, and are sewn by attachment pieces 106 and 107 on both sides of the opening 101. Fixed. Thus, the bag body 102 is disposed inside the cover 17. A hand or even a part of the forearm can be inserted into the bag body 102 from the opening 101 and the manual knob 14 can be operated. The length a3 along the opening 101 of the bag body 102 may be 22 cm, and the depth a4 may be 18.7 cm.
[0061]
The bag body 102 is made of a flexible sheet body, and the bag body 102 may be corona dischargeable or conductive. When the sheet body of the bag body 102 is conductive, the bag body 102 is electrically connected to the cover 17 by being sewn by the attachment pieces 106 and 107. The sheet body constituting the bag body 102 is made of the same material as the sheet body 88 shown in FIG. 23 described below, and may be configured to be conductive.
[0062]
FIG. 24 is a cross-sectional view of the sheet body 88 constituting the cover 17. The cover 17 is configured by covering both surfaces of a cloth 109 with coating layers 110 and 111 made of a conductive rubber material. As a result, the strength of the sheet body 88 is improved. Therefore, when the worker wearing the respirator 1 is working, even if the cover 17 is caught by an external obstacle, the sheet member 88 constituting the cover 17 is prevented from being damaged. , The strength will be improved. The covering layers 110 and 111 include carbon powder or metal powder and have conductivity, for example, 10⁶Has a resistance value of Ω. The fabric 109 may be electrically insulating or conductive.
[0063]
When the bag body 102 is made of a sheet body having a corona discharge function, the sheet body is made of a woven or knitted fabric made of a blended yarn of a synthetic resin fiber such as polyester and a metal or carbon fiber such as stainless steel. Further, it may be a non-woven fabric. The stainless steel fiber may be used by mixing 0.2 to 10% of the sheet body. Furthermore, the corona discharge function can be further enhanced by adding 3 to 5% of stainless steel fibers in a fabric in which stainless steel fibers are uniformly dispersed by about 0.2 to 1%, for example, at intervals of 2.5 to 5 cm. it can. The bag body 102 may be formed of a sheet body having a corona discharge function having other configurations.
[0064]
In the configuration in which the bag body 102 is formed of a sheet body having a corona discharge function, as shown in FIG. 25, static electricity charged on the charged object 113 such as a fiber made of an electrically insulating material of the sheet body is generated by weak corona discharge. And flows to the ground conductor 114 such as an external sharp projection. Corona discharge generated in a fibrous conductor has a very low discharge energy density and is very unlikely to become an ignition source for combustible materials.
[0065]
【The invention's effect】
According to the present invention of claim 1, by attaching the contact piece to the face body, the contact piece comes into contact with the face, and the fixed resistor is connected to the contact piece, thereby being sequentially connected to the fixed resistor. Therefore, it is possible to prevent the electrical resistance value between the respiratory component and the contact piece from changing according to the ambient temperature, thereby stabilizing the electrostatic conduction performance. Accordingly, it is possible to achieve excellent electrostatic conducting performance over a wide temperature range and prevent electrostatic charging.
[0066]
Furthermore, according to the present invention, it is possible to easily measure the electrical resistance value between the contact piece and the component using an insulation resistance meter or the like, and as described in relation to the prior art, Inspection is easily performed without the need for inspection jigs such as part models.
[0067]
Further in accordance with the present invention, the electrical resistance value is about 10 as previously described.^Five-10⁷Therefore, even if, for example, a metal part of the respirator comes into contact with a commercial power source of 100 to 400 V, the wearer has no fear of electric shock, and the generated static electricity is fixed resistance from the components of the respirator. It is possible to reliably escape from the contact piece via the container to the conductive floor (or the ground) via the human body.
[0068]
  furtherAccording to the present invention, the fixed resistor is connected to each of the two conductors having the electrically insulating coating layer and is covered with the electrical insulator, so that the metal part such as the lead wire of the fixed resistor and the conductor is not formed. Contact with water vapor and water droplets is prevented, electrical connection is ensured, reliability is improved, and life can be extended.
[0069]
  Claim2According to the present invention, the fixed resistor is arranged in the vicinity of the inlet of the intake gas so that the dried intake gas exists in the vicinity of the fixed resistor. As described above, the lead wire, the conductive wire, and the like are prevented from being corroded by water vapor and water droplets, and the reliability is improved and the life can be extended.
[0070]
  Claim3According to the present invention, the flexible cover prevents static charge of the portion made of the electrically insulating material in the pressure vessel, the blocking valve, the pressure reducing valve and the backpack, and even if the static charge is charged, It is possible to prevent discharge with the members of this, and to prevent the occurrence of sparks, and furthermore, an opening is formed in the cover for operating the manual knob of this stop valve, and this opening has a corona discharge function or is conductive Since the bag body is fixed, the manual knob can be easily angularly displaced by 180 degrees with one hand, for example, so that the closing valve can be opened or closed. As described above, it is possible to operate the knob for one rotation operation in a large range such as 180 degrees. Moreover, according to the present invention, even in the state where the opening of the cover remains open, the inside of the cover is prevented by the bag, and discharge of static electricity with an external object can be prevented. Safety is improved.
[0071]
  Claim4According to the present invention, by using the contact piece and the fixed resistor, it is possible to prevent the fluctuation of the electric resistance value depending on the ambient temperature, to stabilize the electrostatic conductive performance, and to configure the contact piece and the respirator. The electrical resistance value between the elements can be measured by, for example, an insulation resistance meter to facilitate the inspection, and there is no need to use an inspection jig such as a human head model related to the above-described prior art. Furthermore, by using the cover and the bag body fixed to the opening of the cover, it is possible to prevent static electricity from being charged in the components such as the pressure vessel, the blocking valve, the pressure reducing valve and the back cover covered with the cover, and Prevents the occurrence of sparks due to electric discharge with the member, and even if the opening remains open, the opening is prevented by the bag body, and as described above, the electrostatic charge is prevented. Sealed, it is possible to prevent the discharge of static electricity. By using the bag body, it is possible to easily perform the angular displacement operation of the manual knob of the closing valve, and to rotate it with a relatively large angular displacement amount by holding the manual knob with one hand. The operability is good. If you try to rotate the manual knob by grabbing it from the top of the cover, it is difficult to securely grasp the manual knob and the amount of angular displacement per stroke cannot be increased. The operability is bad. The present invention solves this problem.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view in which a part of a face body 2 of an electrostatic conductive respirator 1 according to an embodiment of the present invention is cut away.
FIG. 2 is a diagram showing an overall configuration of the electrostatic conductive respirator 1;
FIG. 3 is a simplified side view of the electrostatically conductive respirator 1;
FIG. 4 is a system diagram showing a gas flow of the electrostatic conduction type respirator 1;
FIG. 5 is a simplified diagram showing a path through which static electricity leaks from the electrostatic conductive respirator 1 according to the present invention.
6 is a front view of the face piece 2. FIG.
7 is a side view of the face piece 2. FIG.
FIG. 8 is a partial cross-sectional view seen from the side of the face piece 2.
FIG. 9 is a front view showing a part of the inside of the face piece 2 as viewed from the arrow IX in FIG. 7;
FIG. 10 is a cross-sectional view of the conductive contact piece 27 and the vicinity thereof as seen from the side.
11 is a front view showing the overall configuration of a resistance member 47 including a fixed resistor 28. FIG.
12 is a cross-sectional view of the vicinity of the fixed resistor 28. FIG.
13 is a cross-sectional view perpendicular to the axis of the medium pressure hose 16. FIG.
FIG. 14 is a simplified perspective view showing a connecting lead wire 69 that is a ground wire used for releasing static electricity and a connection state of the connecting lead wire 69;
15 is a cross-sectional view of the vicinity of a caulking piece 70. FIG.
16 is a cross-sectional view showing a configuration for connecting a connecting lead wire 69 to a covering body 71. FIG.
17 is a perspective view showing a configuration for connecting a connecting lead wire 69 to a coil-shaped covering body 71. FIG.
FIG. 18 is a view showing the conductive cover 17 with its front side turned upside down.
FIG. 19 is a diagram in which the back of the cover 17 is turned over.
FIG. 20 is a diagram showing the details of the corners of the cover 17 in an inverted state.
21 is a simplified cross-sectional view of fastener 89. FIG.
22 is a plan view showing a part of FIG. 19 near the corner 96 of the sheet body 88 of the cover 17. FIG.
23 is a perspective view of the flexible bag body 102 attached to the opening 101 as seen from the inside of the cover 17. FIG.
24 is a cross-sectional view of a sheet body 88 constituting the cover 17. FIG.
FIG. 25 is a view showing a discharge mechanism of a fiber having a corona discharge function.
[Explanation of symbols]
1 Electrostatic conductive respiratory
Dihedron
3 human body
4 face
5 Pressure vessel
6 Backpack
7 Metal plate
8 Backpack band
14 Stop valve
15 Pressure reducing valve
16 Intake pipe
17 Cover
18 Manual knob
22 Pressure demand valve
23 Expiratory valve
24 Pressure indicator
25 Flexible pressure indicator
26 Alarm
27 Conductive contact piece
28 Fixed resistors
33 Front plate
35 Annular seal member
35a inner mask
37 jaws
38 Lower part of seal
39 Lower front of seal
40 Mounting part
41 space
47 Resistance member
49, 50 Lead wire
51,52 Coated conductor
53,55 lead
54, 56 Caulking connection piece
57,58 coating layer
59 Electrical insulation
60 Heat-shrinkable tube
65 pipe body
66 Cover
67 Mounting piece
69 Connecting wire
70,72 Caulking piece
71 Coiled sheath
88 conductive sheet
89 Slide fastener
90 Operation piece
91, 92, 93, 94 Notch
101 opening
102 Flexible bag

Claims (4)

A metal conductive contact piece provided on the face body at a position in contact with the face when the face body is worn,
Provided in the face piece, one end connected to the contact piece, the other end is connected to the conductive connection port facepiece for connecting the supply valve, a fixed resistor having a resistance value of 10 ⁵ to 10 ⁷ Omega Including
The electrical resistance of the respiratory organ is 10 ⁵ to 10 ⁷ Ω ,
The one end and the other end of the fixed resistor are respectively connected to two conductive wires covered with a covering layer made of an electrically insulating material,
Covered by an electrical insulator across the one end of the fixed resistor and one conductor and across the other end and the other conductor;
The one conductive wire is connected to a contact piece, and the other conductive wire is connected to a connection port of a face body to which the supply valve is connected . 2. The electrostatic conductive respirator according to claim 1, wherein the fixed resistor is disposed in the vicinity of an inlet to which inhaled gas is supplied to the face piece. Intake gas in the pressure vessel is led to the pressure reducing valve from the blocking valve that is attached to the pressure vessel and can be opened and closed by operating a manual knob, and is supplied to the face body through the intermediate pressure hose and the supply valve.
The pressure vessel is an electrostatically conductive respirator that is removably attached to a metal back supported on the back of the wearer.
A flexible cover made of a conductive sheet, covering a pressure vessel, a blocking valve, a pressure reducing valve and a backpack, and having an opening that can be opened and closed near the position of a manual knob of the blocking valve;
Consists of a sheet body having a corona discharge function or a conductive sheet body, which is connected and fixed to the opening, is arranged on the inside of the cover, and the wrist is inserted inward from the opening to operate the manual knob of the closing valve. A flexible bag for
An electrostatically conductive respirator characterized in that the cover is electrically connected to the wearer. Intake gas in the pressure vessel is led to the pressure reducing valve from the blocking valve that is attached to the pressure vessel and can be opened and closed by operating a manual knob, and is supplied to the face body through the intermediate pressure hose and the supply valve.
The pressure vessel is an electrostatically conductive respirator that is removably attached to a metal back supported on the back of the wearer.
A flexible cover made of a conductive sheet, covering a pressure vessel, a blocking valve, a pressure reducing valve and a backpack, and having an opening that can be opened and closed near the position of a manual knob of the blocking valve;
Consists of a sheet body having a corona discharge function or a conductive sheet body, which is connected and fixed to the opening, is arranged on the inside of the cover, and the wrist is inserted inward from the opening to operate the manual knob of the closing valve. A flexible bag for
A conductive contact piece provided on the face body at a position in contact with the face when the face body is worn,
Provided on the face plate, one end is connected to the contact piece, and the other end is electrically connected to the pressure reducing valve, the blocking valve, the pressure indicator air guide tube, the pressure indicator, the intermediate pressure hose, the supply valve and the cover. 10 ^Five -10 ⁷ And a static resistor having a resistance value of Ω.

Images